End modification to prevent over-representation of fragments

ABSTRACT

The invention relates to a method of preparing a 5′ and 3′ modified library of template polynucleotides and also the use of the 5′ and 3′ modified library of templates in methods of solid-phase nucleic acid amplification. In particular, the invention relates to a method of preparing a 5′ and 3′ modified library of template polynucleotides which have common sequences at their 5′ ends and at their 3′ ends, wherein over-representation of “end” sequences of the primary polynucleotide molecules from when the 5′ and 3′ modified library is generated is greatly reduced or prevented.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a National Stage Application claiming the priority of PCT Application No. PCT/GB2007/000427, filed Feb. 7, 2007, which in turn, claims priority from U.S. Application Ser. No. 60/771,358, filed Feb. 8, 2006. Applicants claim the benefits of 35 U.S.C. §120 as to the PCT application and priority under 35 U.S.C. §119 as to the said United States application, and the entire disclosures of both applications are incorporated herein by reference in their entireties.

FIELD OF THE INVENTION

The invention relates to a method of preparing a 5′ and 3′ modified library of template polynucleotides and also the use of the 5′ and 3′ modified library of templates in methods of solid-phase nucleic acid amplification. In particular, the invention relates to a method of preparing a 5′ and 3′ modified library of template polynucleotides which have common sequences at their 5′ ends and at their 3′ ends, wherein over-representation of “end” sequences of the primary polynucleotide molecules from whence the 5′ and 3′ modified library is generated is greatly reduced or prevented.

BACKGROUND TO THE INVENTION

Molecular biology and pharmaceutical drug development now make intensive use of nucleic acid analysis. The most challenging areas are whole genome sequencing, single nucleotide polymorphism detection, screening and gene expression monitoring, which typically require analysis of large amounts of nucleic acid.

One area of technology which revolutionised the study of nucleic acids was the development of nucleic acid amplification techniques, such as the polymerase chain reaction (PCR). Amplification reactions, such as PCR, can enable the user to specifically and selectively amplify a particular target nucleic acid of interest from a complex mixture of nucleic acids. However, there is also an ongoing need for nucleic acid amplification techniques which enable simultaneous amplification of complex mixtures of templates of diverse sequence, such as genomic DNA fragments (e.g. “whole genome” amplification) or cDNA libraries, in a single amplification reaction.

PCR amplification cannot occur in the absence of annealing of forward and reverse amplification primers to primer binding sequences in the template to be amplified under the conditions of the annealing steps of the PCR reaction, i.e. if there is insufficient complementarity between primers and template. Some prior knowledge of the sequence of the template is therefore required before one can carry out a PCR reaction to amplify a specific template, unless random primers are used with a consequential loss of specificity. The user must usually know the sequence of at least the primer-binding sites in the template in advance so that appropriate primers can be designed, although the remaining sequence of the template may be unknown. The need for prior knowledge of the sequence of the template increases the complexity and cost of PCR amplification of complex mixtures of templates, such as genomic DNA fragments.

WO 98/44151 and WO 00/18957 both describe methods of forming polynucleotide arrays based on “solid-phase” nucleic acid amplification wherein the amplification products are immobilised on a solid support in order to form arrays comprised of nucleic acid clusters or “colonies”. Each cluster or colony on such an array is formed from a plurality of identical immobilised polynucleotide strands and a plurality of identical immobilised complementary polynucleotide strands. The arrays so-formed are generally referred to herein as “clustered arrays” and their general features will be further understood by reference to WO 98/44151 or WO 00/18957, the contents of both documents being incorporated herein in their entirety by reference.

As aforesaid, the solid-phase amplification methods of WO 98/44151 and WO 00/18957 are essentially carried out on a solid support. Like any amplification reaction these methods require the use of forward and reverse amplification primers (which may be identical or different) capable of annealing to a template to be amplified. In the methods of WO 98/44151 and WO 00/18957 both primers are immobilised on the solid support at the 5′ end. Other forms of solid-phase amplification are known in which only one primer is immobilised and the other is present in free solution (Mitra, R. D and Church, G. M., Nucleic Acids Research, 1999, Vol. 27, No. 24).

In common with all amplification techniques, solid-phase PCR amplification requires the use of forward and reverse amplification primers which include “template-specific” nucleotide sequences which are capable of annealing to sequences in the template to be amplified, or the complement thereof, under the conditions of the annealing steps of the amplification reaction. The sequences in the template to which the primers anneal under conditions of the amplification reaction may be referred to herein as “primer-binding” sequences.

Certain embodiments of the methods described in WO 98/44151 and WO 00/18957 make use of “universal” primers to amplify templates comprising a variable target portion that it is desired to amplify flanked 5′ and 3′ by common or “universal” primer binding sequences. The “universal” forward and reverse primers include sequences capable of annealing to the “universal” primer binding sequences in the template construct. The variable target portion may itself be of known, unknown or partially known sequence. This approach has the advantage that it is not necessary to design a specific pair of primers for each target to be amplified; the same primers can be used for amplification of different targets provided that each target is modified by addition of the same universal primer-binding sequences to its 5′ and 3′ ends. The variable target sequence can therefore be any DNA fragment of interest. An analogous approach can be used to amplify a mixture of targets, such as a plurality or collection of target nucleic acid molecules (e.g. genomic DNA fragments), using a single pair of universal forward and reverse primers, provided that each target molecule in the collection is modified by the addition of the same universal primer-binding sequences.

Such “universal primer” approaches to PCR amplification, and in particular solid-phase PCR amplification, are advantageous since they enable multiple template molecules of the same or different, known or unknown sequence to be amplified in a single amplification reaction, which may be carried out on a solid support bearing a single pair of “universal” primers. Simultaneous amplification of a mixture of templates of different sequences by PCR would otherwise require a plurality of primer pairs, each pair being complementary to each unique template in the mixture. The generation of a plurality of primer pairs for each individual targets is not a viable option for complex mixtures of targets.

The addition of universal priming sequences onto the ends of targets to be amplified can be achieved by a variety of methods known to those skilled in the art. For example, a universal primer consisting of a universal sequence at its 5′ end and a degenerate sequence at its 3′ end can be used in a PCR (DOP-PCR, eg PNAS 1996 vol 93 pg 14676-14679) to amplify fragments randomly from a complex target or a complex mixture of targets. The degenerate 3′ portion of the primer anneals at random positions on DNA and can be extended to generate a copy of the template that has the universal sequence at its 5′ end.

Alternatively, adapters that contain universal priming sequences can be ligated onto the ends of targets. The adapters may be single-stranded or double-stranded. If double-stranded, they may have overhanging ends that are complementary to overhanging ends on the target molecules that have been generated with a restriction endonuclease. Alternatively, the double-stranded adapters may be blunt, in which case the targets are also blunt ended. The blunt ends of the targets may have been formed during a process to shear the DNA into fragments, or they may have been formed by an end repair reaction, as would be well known to those skilled in the art. The ends of the targets may be treated to obtain a single 3′-overhang.

A single adapter or two different adapters may be used in a ligation reaction with targets. If a target has been manipulated such that its ends are the same, i.e. both are blunt or both have the same overhang, then ligation of a single compatible adapter will generate a target sequence with that adapter on both ends. However, if two compatible adapters, adapter A and adapter B, are used, then three permutations of ligated products are formed: target with adapter A on both ends, target with adapter B on both ends, and target with adapter A on one end and adapter B on the other end. This last product is, under some circumstances, the only desired product from the ligation reaction and consequently additional purification steps are necessary following the ligation reaction to purify it from the ligation products that have the same adapter at both ends.

SUMMARY OF THE INVENTION

In a first aspect the invention provides a method of generating a 5′ and 3′ modified library of template polynucleotide molecules from one or more primary polynucleotide molecules, wherein said primary polynucleotide molecules are modified primary polynucleotide molecules comprising a modification at or near each 5′-terminus that prevents ligation to their 5′-termini; said method comprising the step of:

-   -   a) Fragmenting the modified primary polynucleotide molecules to         produce target polynucleotide duplexes, wherein the target         polynucleotide duplexes comprise modified target polynucleotide         duplexes comprising the modification at or near a 5′ terminus         and unmodified target polynucleotide duplexes comprising two         ligatable termini;     -   b) ligating adapter polynucleotides to the two ligatable termini         of the unmodified target polynucleotide duplexes to form one or         more adapter-target-adapter constructs;     -   c) carrying out an amplification reaction, wherein a primer         oligonucleotide is annealed to both 5′-terminal adapter portions         of each of the adapter-target-adapter constructs and extended by         sequential addition of nucleotides to form, extension products         complementary to each strand of each of the adapter-target         constructs, wherein the extension products have common sequences         at their 5′ ends and common sequences at their 3′ ends and         collectively provide a 5′ and 3′ modified library of template         polynucleotide molecules;     -   wherein said method prevents the over-representation of the         sequences at either end of the primary polynucleotide molecules         in the 5′ and 3′ modified library of template polynucleotide         molecules.

In an aspect of the method, the modification at or near the 5′ terminus of the primary polynucleotide molecules is introduced using an amplification reaction. Such amplification reactions may comprise one or more modified amplification primers. In a further embodiment of the method, the modified amplification primers comprise a 5′-amino or 5′-biotin modification. It is also envisioned that modified amplification primers may comprise a modification that prevents nucleotide polymerase mediated copying of the full length of the primer. Modified amplification primers may also comprise an abasic site.

In an embodiment of the method wherein the primary polynucleotides are double stranded, the modification at or near the 5′ terminus of the primary polynucleotides may be introduced using an enzyme. In a further aspect, the modification is a modified deoxynucleoside triphosphate introduced using a nucleotide polymerase. In yet a further aspect, the modification is a dideoxynucleoside triphosphate introduced using a terminal transferase.

In accordance with an aspect of the method, fragmentation of the primary polynucleotide molecules may be achieved by sonication or nebulization.

In an aspect of the invention, the primary polynucleotide molecules are DNA molecules. In an embodiment of the method, the modified primary polynucleotide molecules are generated by polymerase chain reaction (PCR).

In an aspect of the method, the modified primary polynucleotide molecules are at least 5000 base pairs in length.

In another aspect of the method, at least one of the amplification primers extends beyond the 5′-bases of the adapter.

In yet another aspect of the method, the adapter contains a double stranded region and at least one single stranded region.

The present method may further comprise the steps of:

-   -   (d) preparing clusters from the 5′ and 3′ modified library of         template polynucleotide molecules; and     -   (e) sequencing the clusters by sequencing by synthesis.

The present invention also encompasses a 5′ and 3′ modified library of template polynucleotide molecules prepared using an aspect of the method of the invention. The present invention also encompasses an array comprising a 5′ and 3′ modified library of template polynucleotide molecules prepared using an aspect of the method of the invention. The present invention further envisions methods of using the 5′ and 3′ modified library prepared using an aspect of the method of the invention in sequencing and methods of using the array comprising a 5′ and 3′ modified library of template polynucleotide molecules prepared using an aspect of the method of the invention in sequencing.

DETAILED DESCRIPTION OF THE INVENTION

In a first aspect the invention provides a method of generating a 5′ and 3′ modified library of template polynucleotide molecules from one or more primary polynucleotide molecules characterised in that said method prevents over-representation of the sequences at either end of the primary polynucleotide molecules in the 5′ and 3′ modified library of template polynucleotide molecules. Accordingly, the method of the present invention addresses the problem of over-representation of terminal sequences of primary polynucleotides in 5′ and 3′ modified libraries generated therefrom.

UK Application Patent application Number 0522310.2, herein incorporated by reference, is a method that uses a single adapter in a ligation reaction to generate a 5′ and 3′ modified library of template polynucleotides each of which have common, but different, universal primer sequences at their 5′ and 3′ ends. The method can be applied to preparing simple or complex mixes of templates for amplification, for example a solid surface, using primer sequences, with no prior knowledge of the template sequences and is applicable to the preparation of templates from complex samples such as whole genomes or mixtures of cDNAs, as well as mono-template applications.

Although the above method works well, the present inventors have discovered that when sequencing or cloning nucleic acid fragments produced from amplified nucleic acid sequences, the ends of the amplified nucleic acid sequences are over-represented in comparison to those sequences internal to the ends of the amplified nucleic acid sequences (i.e., central or core sequences).

Not wishing to be bound by hypothesis, it is believed that accumulation of damage during fragmentation of nucleic acid sequences may affect or have greater affect on central or core sequences along the length of the original nucleic acid strand, as compared to those sequences at, or proximal, to either end. By way of an oversimplified example, if a nucleic acid strand 100 kbps in length was fragmented into 100 pieces 1 Kbps in length, the two pieces at either end of the strand would have one broken, fragmented end compared to those 98 central pieces derived from the middle of the strand which would have two fragmented ends. When the sample is processed and sequenced, the ‘two’ end fragments appear at a much higher frequency than the 98 ‘central’ fragments. If the sequencing is performed on amplified isolated individual molecules, a large number of the amplified ‘clones’ or ‘clusters’ derive from the ends of the sample, meaning that the sequencing of the central 98 pieces is less efficient due to the large over-representation of the two ends.

Without being limited to the hypothesis, the present inventors believe that when the end of the nucleic acid is derived from a synthetic oligonucleotide primer, the end of the strand is always a clean, blunt ended duplex that works very efficiently for ligation. However, when the end of the nucleic acid is derived from a random shearing process and enzymatic polishing, the end is less chemically clean, and therefore less efficient in subsequent ligation reactions. Thus it is likely that the efficiency of end-repair will also be lower for fragments that have two ends to be repaired rather than one. It is also likely that damage within each fragment could also affect the efficiency of amplification in downstream steps, and thus the fragments derived from the central region of the fragmented sample contain two polished ends, whereas the fragments from the end region contain one synthetic end and one polished end.

Thus such over-representation gives rise to a bias leading effectively to redundancy in both sequencing and cloning steps. The present invention addresses this previously unrealized problem by providing an improved method which reduces or removes over-representation of end sequences in a nucleic acid 5′ and 3′ modified library, and thereby is an improvement on the original method wherein the starting nucleic acid sample is a PCR product or other amplicon or other blunt ended duplex.

The term “5′ and 3′ modified library” refers to a collection or plurality of template molecules which share common sequences at their 5′ ends and common sequences at their 3′ ends. Use of the term “5′ and 3′ modified library” to refer to a collection or plurality of template molecules should not be taken to imply that the templates making up the 5′ and 3′ modified library are derived from a particular source, or that the “5′ and 3′ modified library” has a particular composition. By way of example, use of the term “5′ and 3′ modified library” should not be taken to imply that the individual templates within the 5′ and 3′ modified library must be of different nucleotide sequence or that the templates be related in terms of sequence and/or source.

In its various embodiments the invention encompasses formation of so-called “monotemplate” libraries, which comprise multiple copies of a single template molecule, each having common sequences at their 5′ ends and their 3′ ends, as well as “complex” libraries wherein many, if not all, of the individual template molecules comprise different target sequences (as defined below), although all share common sequences at their 5′ ends and 3′ ends. Such complex template libraries may be prepared using the method of the invention starting from a complex mixture of target polynucleotides such as (but not limited to) random genomic DNA fragments, cDNA libraries etc. The invention also extends to “complex” libraries formed by mixing together several individual “monotemplate” libraries, each of which has been prepared separately using, the method of the invention starting from a single type of target molecule (i.e. a monotemplate). In particular embodiments more than 50%, or more than 60%, or more than 70%, or more than 80%, or more than 90%, or more than 95% of the individual polynucleotide templates in a complex 5′ and 3′ modified library may comprise different target sequences, although all templates in a given 5′ and 3′ modified library will share common sequence at their 5′ ends and common sequence at their 3′ ends.

Use of the term “common” is interpreted as meaning common to all templates in the 5′ and 3′ modified library. As explained in further detail below, all templates within the 5′ and 3′ modified library will contain regions of common sequence at their 5′ and 3′ ends, wherein the common sequence at the 5′ end of each individual template in the 5′ and 3′ modified library is not identical and not fully complementary to the common sequence at the 3′ end of said template.

Use of the term “template” to refer to individual polynucleotide molecules in the 5′ and 3′ modified library indicates that one or both strands of the polynucleotides in the 5′ and 3′ modified library are capable of acting as templates for template-dependent nucleic acid polymerisation catalysed by a polymerase. Use of this term should not be taken as limiting the scope of the invention to libraries of polynucleotides which are actually used as templates in a subsequent enzyme-catalysed polymerisation reaction.

The term target is used to signify a fragmented polynucleotide of substantially unknown sequence. ‘Targets’ that are modified with known ends become ‘templates’ suitable for amplification.

Use of the term “ends” is a general term interpreted as referring to regions of sequence at (or proximal to) either end of a nucleic acid sequence. For example when referring to single stranded nucleic acid molecules the term refers to the 3′ and/or 5′ “ends”. The length of the “ends” may be defined by the length of a synthetic oligonucleotide sequence, or may be derived from the length of the average length of the fragments. If the average length of the fragments in a fragmented sample is 100-200 base pairs, the length of the ‘end’ fragments will also be 100-200 base pairs. In a duplex where two complementary single stranded nucleic acid molecules are base paired then such a duplex will comprise two “ends” each with a 3′ end from one single stranded nucleotide sequence and a 5′ end from the other of the single stranded nucleotide sequences.

The term “over-representation” is used to refer to the case where the relative amount of a particular sequence, for example within a 5′ and 3′ modified library, is increased in comparison to other sequences within the 5′ and 3′ modified library. In a 5′ and 3′ modified library for example, it is desirable that the relative level of any one sequence when compared to the relative level of any other sequence in the 5′ and 3′ modified library is in an approximately equal ratio of 1:1. In an embodiment wherein the target polynucleotide molecules are random segments (fragments) of the primary polynucleotide sequence, if the 5′ and 3′ modified library covers the primary polynucleotide sequence to a depth ‘d’, then the average number of template polynucleotide molecules covering any point in the primary polynucleotide sequence should also be ‘d’. Hence the composition of template polynucleotide molecules proportionally reflects the overall composition of the primary polynucleotide molecules. In context preventing over-representation therefore refers to the process of maintaining the relative abundance of particular nucleic acid sequences in a sample or 5′ and 3′ modified library such that there is uniform coverage of any point in the primary polynucleotide sequence by approximately equal numbers of template polynucleotide molecules.

In a first step modified primary polynucleotide molecules are prepared by adding a modification to the 5′-ends of the primary polynucleotide molecules.

In a particular embodiment the primary polynucleotide molecules may originate in double-stranded DNA form (e.g. genomic DNA fragments, PCR and amplification products and the like) or may have originated in single-stranded form, as DNA or RNA, and been converted to dsDNA form. By way of example, mRNA molecules may be copied into double-stranded cDNAs suitable for use in the method of the invention using standard techniques well known in the art. The precise sequence of the primary polynucleotide molecules is generally not material to the invention, and may be known or unknown. In a particular embodiment, the primary polynucleotide molecules are DNA molecules. More particularly, the sequence of the primary polynucleotide molecules is not known. Yet more particularly, the DNA molecules are PCR products. The primary polynucleotide molecules can be a biological sample of nucleic acids. The modified primary polynucleotides can be PCR amplicons from said sample, wherein said amplicons are obtained using primers containing a modification at the 5′-terminus, thus the ‘modified’ primary nucleic acids may only be a small fraction of the original primary sample, for example a ‘modified’ 5000 base pair fragment from a whole genomic ‘primary’ sample.

The sequence of the modified polynucleotide molecules may be the same or different for example, a mixture of modified primary polynucleotide molecules of different sequence may be prepared by mixing a number, greater than one, of individual modified primary polynucleotide molecules.

If the primary polynucleotide molecules are a mixture of short polynucleotide molecules such as DNA or products of around 500-1000 base pairs in length then it may be desirable to prepare a concatemer by ligating the primary polynucleotide molecules together prior to modification of the ends. In such instances the sequence at the terminus of each primary sequence may be unknown, meaning the primary sequence can not be modified using a PCR reaction. The ends of the duplex may however be modified by treatment with a modified nucleotide triphosphate, for example a dideoxynucleotide triphosphate and a nucleotide polymerase or terminal transferase. Thus the ends of the primary polynucleotides may be modified directly prior to fragmentation. The ends of the duplex may also be treated with a further duplex adaptor sequence that prevents amplification of the fragment after the ligation step, for example an abasic primer sequence.

Such modifications could be by a number of means provided that such modifications preclude adaptor ligation and/or copying in a primer extension reaction in later steps of the method. Such modifications are well known in the art and could include by way of non-limiting examples incorporating, by ligation, modified DNA molecules including non-natural nucleotides and/or non-natural backbone linkages, adding chemical modifications (for e.g. biotin) or using a 5′-3′ exonuclease to generate incompatible overhanging ends, enzymatic processes or use of terminal transferase.

It could also be envisaged that the modified primary polynucleotide molecules could be produced by amplification of the primary polynucleotide molecules. In this case amplification primers could be utilised which contain modified DNA molecules including non-natural nucleotides and/or non-natural backbone linkages or chemical modifications such as biotin. On amplification of the primary polynucleotide molecules the modifications would be incorporated into the modified primary polynucleotide molecules to prevent adaptor ligation and/or copying in a primer extension reaction. For example 5′-amino or 5′-biotinylated primers could be utilised during amplification of the primary polynucleotide molecules. The amplification primers could contain modifications such as abasic sites that prevent the polymerase copying to the absolute ends of the primers. The primers thus contain a 5′-overhang that prevents ligation to the 5′-end of the duplex. The amplified products (modified primary polynucleotide molecules) will subsequently comprise the modifications introduced by way of modified amplification primers.

In a particular procedure, the modified primary polynucleotide molecules are fragmented into small fragments (target polynucleotide duplexes), more particularly less than 1000 base pairs in length, even more particularly less than 200 base pairs in length. Fragmentation to a size of less than 50 base pairs is achievable, but not desirable as this is less than the read length of the sequencing reaction. An ideal fragment size is distributed around 100-200 base pairs. Fragmentation of DNA may be achieved by a number of methods including: enzymatic digestion, chemical cleavage, sonication, nebulisation, or hydroshearing, preferably nebulisation.

It will be appreciated by one skilled in the art that not all of the target polynucleotide duplexes produced by this method will contain modifications; generally only those fragments containing sequences from the ends of the modified primary polynucleotide molecules will comprise modifications. As a result of these modifications it is intended that such fragments either will not ligate or are effectively removed from later PCR amplifications by virtue of a failure to amplify.

Preferably the target polynucleotide duplexes will be made blunt-ended by a number of methods known to those skilled in the art. In a particular method, the ends of the fragmented DNA are end repaired with T4 DNA polymerase and Klenow polymerase, a procedure well known to those skilled in the art, and then phosphorylated with a polynucleotide kinase enzyme. A single ‘A’ deoxynucleotide can be added to both 3′ ends of the DNA molecules using Taq polymerase enzyme, producing a one-base 3′ overhang that is complementary to a one-base 3′ ‘T’ overhang on the double-stranded end of the ligation adapter.

In a next step, adaptor polynucleotides are ligated to both ends of the target polynucleotide duplexes to form one or more adaptor-target constructs.

In one embodiment a ligation reaction between an adapter and the target polynucleotide duplexes is performed using a suitable ligase enzyme (e.g. T4 DNA ligase), which joins two copies of the adapter to each target polynucleotide duplexes, one at either end, to form adapter-target constructs. Those target polynucleotide duplexes which comprise modifications will be prevented from ligating to adaptors. The ligated products of this reaction can be purified from unligated adapter by a number of means, including size-inclusion chromatography, preferably by electrophoresis through an agarose gel slab followed by excision of a portion of the agarose that contains the DNA greater in size that the size of the adapter.

After the excess adapter has been removed, unligated target polynucleotide duplexes comprising modifications remain, in addition to ligated adapter-target constructs. The unligated target polynucleotide duplexes may be removed for example by selectively capturing only those target DNA molecules that have adapter attached, followed by washing or by other methods well known in the art. In this manner, end sequences which would previously have been over-represented in a 5′ and 3′ modified library are removed.

In an alternative embodiment, two copies of the adapter are joined to each target polynucleotide duplexes (including those comprising modifications), one at either end, to form adapter-target constructs. In this instance the modification is intended to prevent amplification of adapter-target constructs comprising modification, in ‘downstream’ steps of the method. As before, the products of this reaction can be purified from unligated adapter by a number of means, including size-inclusion chromatography, preferably by electrophoresis through an agarose gel slab followed by excision of a portion of the agarose that contains the DNA greater in size that the size of the adapter.

In a next step, a primer extension reaction is performed in which a primer oligonucleotide is annealed to an adaptor portion of each of the adapter-target constructs and extended by sequential addition of nucleotides to form extension products complementary to at least one strand of each of the adapter-target constructs wherein the extension products and optionally amplification products derived therefrom have common sequences at their 5′ ends and common sequences at their 3′ ends.

As mentioned, in a particular embodiment adapter-target constructs comprising modifications are not efficiently amplified for example, by way of non-limiting example, due to the presence of modified abasic nucleotides. Thus the number of adapter-target constructs comprising modifications are effectively reduced or removed from the 5′ and 3′ modified library.

The precise nucleotide sequences of the common regions of the template molecules in the 5′ and 3′ modified library are generally not material to the invention and may be selected by the user. In a particular embodiment the common sequences must at least comprise “primer-binding” sequences which enable specific annealing of amplification primers when the templates are in use in a solid-phase amplification reaction. The primer-binding sequences are thus determined by the sequence of the primers to be ultimately used for solid-phase amplification. The sequence of these primers in turn is advantageously selected to avoid or minimise binding of the primers to the target portions of the templates within the 5′ and 3′ modified library under the conditions of the amplification reaction, but is otherwise not particularly limited. By way of example, if the target portions of the templates are derived from human genomic DNA, then the sequences of the primers to be used in solid phase amplification should ideally be selected to minimise non-specific binding to any human genomic sequence.

Thus, preventing ligation of adapters to the target polynucleotide duplexes prevents amplification of target polynucleotide sequences derived from the ends of the primary polynucleotide molecules and as a result these sequences are reduced or removed from the 5′ and 3′ modified library. Directly interfering with amplification of the adapter-target constructs derived from the ends of the primary polynucleotide molecules also reduces or completely removes such sequences from the 5′ and 3′ modified library.

In yet another embodiment, a small amount of unmodified primary polynucleotide molecules can be added to the modified primary polynucleotide molecules prior to fragmentation. In this way ‘adding back’ a very small proportion of end sequences ensures that end sequences are represented within the finalised 5′ and 3′ modified library and are not completely removed. In still yet another embodiment, when the modified primary polynucleotide molecules are prepared by amplification, oligonucleotide primers could be used which anneal to sequences outside of the desired amplification product. In this instance a larger amplification product is generated which has sequences at either end not required for 5′ and 3′ modified library preparation. When processed according to the present invention loss of this additional sequence does not matter.

Use of the Template 5′ and 3′ Modified Library

Template libraries prepared according to the method of the invention may be used in essentially any method of nucleic acid analysis which requires further amplification of the templates and/or sequencing of the templates or amplification products thereof. Exemplary uses of the template libraries include, but are not limited to, providing templates for bridging amplification, surface amplification, solid-phase PCR amplification (of either monotemplate or complex template libraries). A particular use is in solid-phase PCR amplification carried out on a solid-support.

Whole-Genome Amplification

Template libraries prepared according to the method of the invention starting from a complex mixture of genomic DNA fragments representing a whole or substantially whole genome provide suitable templates for so-called “whole-genome” amplification. The term “whole-genome amplification” refers to a nucleic acid amplification reaction (e.g. PCR) in which the template to be amplified comprises a complex mixture of nucleic acid fragments representative of a whole (or substantially whole genome)

Solid-Phase Amplification

Once formed, the 5′ and 3′ modified library of templates prepared according to the methods described above can be used for solid-phase nucleic acid amplification.

Thus, in further aspects the invention provides a method of solid-phase nucleic acid amplification of template polynucleotide molecules which comprises:

preparing a 5′ and 3′ modified library of template polynucleotide molecules which have common sequences at their 5′ and 3′ ends using a method according to the first aspect of the invention described herein and carrying out a solid-phase nucleic acid amplification reaction wherein said template polynucleotide molecules are amplified.

The term “solid-phase amplification” as used herein refers to any nucleic acid amplification reaction carried out on or in association with a solid support, such as a bead or planar surface, such that all or a portion of the amplified products are immobilised on the solid support as they are formed. In particular, the term encompasses solid-phase polymerase chain reaction (solid-phase PCR), which is a reaction analogous to standard solution phase PCR, except that one or both of the forward and reverse amplification primers is/are immobilised on the solid support.

Although the invention encompasses “solid-phase” amplification methods in which only one amplification primer is immobilised (the other primer usually being present in free solution), it is preferred for the solid support to be provided with both the forward and the reverse primers immobilised. In practice, there will be a “plurality” of identical forward primers and/or a “plurality” of identical reverse primers immobilised on the solid support, since the amplification process requires an excess of primers to sustain amplification. References herein to forward and reverse primers are to be interpreted accordingly as encompassing a “plurality” of such primers unless the context indicates otherwise.

As will be appreciated by the skilled reader, any given amplification reaction requires at least one type of forward primer and at least one type of reverse primer specific for the template to be amplified. However, in certain embodiments the forward and reverse primers may comprise template-specific portions of identical sequence, and may have entirely identical nucleotide sequence and structure (including any non-nucleotide modifications). In other words, it is possible to carry out solid-phase amplification using only one type of primer, and such single-primer methods are encompassed within the scope of the invention. Other embodiments may use forward and reverse primers which contain identical template-specific sequences but which differ in some other structural features. For example one type of primer may contain a non-nucleotide modification which is not present in the other.

In other embodiments of the invention the forward and reverse primers may contain template-specific portions of different sequence.

In all embodiments of the invention, amplification primers for solid-phase amplification are preferably immobilised by covalent attachment to the solid support at or near the 5′ end of the primer, leaving the template-specific portion of the primer free for annealing to its cognate template and the 3′ hydroxyl group free for primer extension. Any suitable covalent attachment means known in the art may be used for this purpose. The chosen attachment chemistry will depend on the nature of the solid support, and any derivatisation or functionalisation applied to it. The primer itself may include a moiety, which may be a non-nucleotide chemical modification, to facilitate attachment. In a particular embodiment the primer may include a sulphur-containing nucleophile, such as phosphorothioate or thiophosphate, at the 5′ end. In the case of solid-supported polyacrylamide hydrogels (as described below), this nucleophile will bind to a bromoacetamide group present in the hydrogel. A particular means of attaching primers and templates to a solid support is via 5′ phosphorothioate attachment to a hydrogel comprised of polymerised acrylamide and N-(5-bromoacetamidylpentyl) acrylamide (BRAPA).

The 5′ and 3′ modified library of templates prepared according to the first aspect of the invention can be used to prepare clustered arrays of nucleic acid colonies, analogous to those described in WO 00/18957 and WO 98/44151, by solid-phase amplification. The terms “cluster” and “colony” are used interchangeably herein to refer to a discrete site on a solid support comprised of a plurality of identical immobilised nucleic acid strands and a plurality of identical immobilised complementary nucleic acid strands. The term “clustered array” refers to an array formed from such clusters or colonies. In this context the term “array” is not to be understood as requiring an ordered arrangement of clusters.

Use in Sequencing/Methods of Sequencing

The invention also encompasses methods of sequencing amplified nucleic acids generated by solid-phase amplification. Thus, the invention provides a method of nucleic acid sequencing comprising amplifying a 5′ and 3′ modified library of nucleic acid templates using whole genome or solid-phase amplification as described above and carrying out a nucleic acid sequencing reaction to determine the sequence of the whole or a part of at least one amplified nucleic acid strand produced in the whole genome or solid-phase amplification reaction.

Sequencing can be carried out using any suitable “sequencing-by-synthesis” technique, wherein nucleotides are added successively to a free 3′ hydroxyl group, resulting in synthesis of a polynucleotide chain in the 5′ to 3′ direction. The nature of the nucleotide added is preferably determined after each nucleotide addition.

The initiation point for the sequencing reaction may be provided by annealing of a sequencing primer to a product of the whole genome or solid-phase amplification reaction. In this connection, one or both of the adapters added during formation of the template 5′ and 3′ modified library may include a nucleotide sequence which permits annealing of a sequencing primer to amplified products derived by whole genome or solid-phase amplification of the template 5′ and 3′ modified library.

The products of solid-phase amplification reactions wherein both forward and reverse amplification primers are covalently immobilised on the solid surface are so-called “bridged” structures formed by annealing of pairs of immobilised polynucleotide strands and immobilised complementary strands, both strands being attached to the solid support at the 5′ end. Arrays comprised of such bridged structures provide inefficient templates for nucleic acid sequencing, since hybridisation of a conventional sequencing primer to one of the immobilised strands is not favoured compared to annealing of this strand to its immobilised complementary strand under standard conditions for hybridisation.

In order to provide more suitable templates for nucleic acid sequencing it is advantageous to remove substantially all or at least a portion of one of the immobilised strands in the “bridged” structure in order to generate a template which is at least partially single-stranded. The portion of the template which is single-stranded will thus be available for hybridisation to a sequencing primer. The process of removing all or a portion of one immobilised strand in a “bridged” double-stranded nucleic acid structure may be referred to herein as “linearisation”.

Bridged template structures may be linearised by cleavage of one or both strands with a restriction endonuclease or by cleavage of one strand with a nicking endonuclease. Other methods of cleavage can be used as an alternative to restriction enzymes or nicking enzymes, including inter alia chemical cleavage (e.g. cleavage of a diol linkage with periodate), cleavage of abasic sites by cleavage with endonuclease, or by exposure to heat or alkali, cleavage of ribonucleotides incorporated into amplification products otherwise comprised of deoxyribonucleotides, photochemical cleavage or cleavage of a peptide linker.

It will be appreciated that a linearization step may not be essential if the solid-phase amplification reaction is performed with only one primer covalently immobilised and the other in free solution.

In order to generate a linearised template suitable for sequencing it is necessary to remove the complementary strands in the bridged structure formed by amplification so as to leave behind a linearised template for sequencing which is fully or partially single stranded. Most preferably one strand of the bridged structure is substantially or completely removed.

Following the cleavage step, regardless of the method used for cleavage, the product of the cleavage reaction may be subjected to denaturing conditions in order to remove the portion(s) of the cleaved strand(s) that are not attached to the solid support. Suitable denaturing conditions, such as hydroxide, formamide or heat will be apparent to the skilled reader with reference to standard molecular biology protocols (Sambrook et al., 2001, Molecular Cloning, A Laboratory Manual, 3rd Ed, Cold Spring Harbor Laboratory Press, Cold Spring Harbor Laboratory Press, NY; Current Protocols, eds Ausubel et al.).

Denaturation results in the production of a sequencing template which is partially or substantially single-stranded. A sequencing reaction may then be initiated by hybridisation of a sequencing primer to the single-stranded portion of the template.

Thus, the invention encompasses methods wherein the nucleic acid sequencing reaction comprises hybridising a sequencing primer to a single-stranded region of a linearised amplification product, sequentially incorporating one or more nucleotides or oligonucleotide cassettes into a polynucleotide strand complementary to the region of amplified template strand to be sequenced, identifying the base present in one or more of the incorporated (oligo)nucleotide(s) and thereby determining the sequence of a region of the template strand.

One particular sequencing method which can be used in accordance with the invention relies on the use of modified nucleotides that can act as chain terminators. Once the modified nucleotide has been incorporated into the growing polynucleotide chain complementary to the region of the template being sequenced there is no free 3′-OH group available to direct further sequence extension and therefore the polymerase can not add further nucleotides. Once the nature of the base incorporated into the growing chain has been determined, the 3′ block may be removed to allow addition of the next successive nucleotide. By ordering the products derived using these modified nucleotides it is possible to deduce the DNA sequence of the DNA template. Such reactions can be done in a single experiment if each of the modified nucleotides has attached thereto a different label, known to correspond to the particular base, to facilitate discrimination between the bases added at each incorporation step. Alternatively, a separate reaction may be carried out containing each of the modified nucleotides separately.

The modified nucleotides may carry a label to facilitate their detection. Preferably this is a fluorescent label. Each nucleotide type may carry a different fluorescent label. However the detectable label need not be a fluorescent label. Any label can be used which allows the detection of an incorporated nucleotide.

One method for detecting fluorescently labelled nucleotides comprises using laser light of a wavelength specific for the labelled nucleotides, or the use of other suitable sources of illumination. The fluorescence from the label on the nucleotide may be detected by a CCD camera or other suitable detection means.

The invention is not intended to be limited to use of the sequencing method outlined above, as essentially any sequencing methodology which relies on successive incorporation of nucleotides or oligonucleotides into a polynucleotide chain can be used. Suitable alternative techniques include, for example, Pyrosequencing™, FISSEQ (fluorescent in situ sequencing), MPSS (massively parallel signature sequencing) and sequencing by ligation-based methods.

The target polynucleotide to be sequenced using the method of the invention may be any polynucleotide that it is desired to sequence. Using the template 5′ and 3′ modified library preparation method described in detail herein it is possible to prepare template libraries starting from essentially any double or single-stranded target polynucleotide of known, unknown or partially known sequence. With the use of clustered arrays prepared by solid-phase amplification it is possible to sequence multiple targets of the same or different sequence in parallel.

The invention will be further understood with reference to the following non-limiting experimental example:

EXAMPLE Experimental Overview

Long range PCR was performed on a BAC vector (bcX98521) containing a human genomic insert using two-sets of primers

Set 1: 5′CGAGGAACTCAGCACTCATC (SEQ ID NO: 1) 5′ATGCCGAGGAAGAAGCCATT (SEQ ID NO: 2) Set 2 5′TTTnTGGAACAGCCGCTCTCACCT (SEQ ID NO: 3) 5′CCCnTCCTGGAGGGAAGTGACTAT (SEQ ID NO: 4)

Set 2 primers have an abasic nucleotide at position ‘n’ in their sequence.

The resultant PCR product from primer set 1 is as follows:

CGAGGAACTCAGCACTCATCCTCACCCAGCAGGGCATAAGGGTTTCGGCCAGCCAGGCTG (SEQ ID NO: 5) GACCCTGGAGCCGAGGTTGGGGTCTCCTCATCCCCTTCTCCCTCCTCATCCGCATCCCGG TCCTCCTCTCCCTCCTCCTCACAGGAGCTGCTCAGCTCTTCCTCTTCCTCCTCCTCCTCG TCACCTGCTGGCCCCACCCTGCCCTGCAAAACCACCAGCTCCGTGGTCTCTGGATGGGAC TCCCAGGTGCCTGGGGAACCAAAACAAGAAAAAAATGGAGGAGAGTTTTGAGCAAGAACT AAAGCCAAGGAAAGATGGGGAAGAGGCAAAGACTAGGAATAACAATAATCTTTAGAGCTG CTGGCATTCATTCATTCATCCATTCATTCAACTTCCTATGTGCAGATTGCTGAACAGAAC CTTTGTGCACATCAACTTCAATCTTTACAATCACTATGCTAAGGGTCAATTATTACCCTC AGTTTGCAGATCAGGAAAATATCACAGATGTTAAGTAACAGAGCTAGCCAACAGGTACAG AATCCAGGTTTGACCCTCTCTCTGGCCACAAAGCCCACACCCTTTTACCTACGCTATAGC AGGGGGCTGGGGAAGAATATCTGGGCTCTGACCTTTCTGTTCACTGTAGCCTGGGGGATG AAAACACAGGCTGAGGCGGCCGTCCACTGCCAGCCGCAAGAGACTGTTGGCTGCTCTGTA CACATCATTCCGAGCCGCCTTGGCTGTCTTGTAACCACGTTTCTCTGCCCAGGCTGGAGG AAGAAAAGAATAATGGAAAGGGAAAGCATTAACCAGGTACCAGTTATACTCCCACTCCCA TAACACAGTCCTTCCAGTTTTCCCCAAAACATTCCAGGCCAGAGATCTTACTGGCTATGC AACAAAAATCTAGGGGTGAGTGGACAGCAGCTTCATCAATGGCAGAATCTCTGAGGAGAG GAAAGGAGACAGGGAAGGGTAAAAGGCGAGGCAGGTAAGGAAGAGCAGCTGAAACCAGGT GGGGCGAAGCCAGGCACATGGAACTCACCTTCACAGATGTCCCAGGCACACCAGGGGTGT TCCGCTGAGGGGTCCTCAGCCTCTGGGTGGCGCAGGTGGAGCAGGGCCTGCACGGGAATT CGGGAGGCCAGGTAGCCCACAGCAGTGTAGGGCTCCTGGATCTGGGCGATAGGGTAGATC CCCGCCAGAACCTGAGGGAAATGAGCACTCAGTACTTTCCTCAATGTCCCACCTTCTCTC TTTCCCTTACCCACCCTCCCCGTCATACCTGCAACTGCCTAGGCAGAAGAGATGGGAAGA TGAGGCCTGGGCAGTCACAGAGCTTCACAGAGGGGGTAAGAAAGTAGGTCTGAAAGTATC GGGTATGGCCCGGGGTTCTGGAGACACTCACGACTTTCCGCCCCACCAGCCCATTGATCA GCGAGGACTTTCCCACATTAGGGAAACCTGAGGAAGGCAAGGAAAATTAACGTTTAACAG GTTTCTACTCTGTGATGGGACTTGGTGCTATACCTATAGGTAAAAGGGGAACTAAGGCTC AGAAATTAAGGAAATGGTATTGCAGAATACAAATCACGCTCTGGGCTGCCAGGGTTAAAT CCTGGCCCTTCCACTTACCAGCTTTGTGATGTCAGGGCAACTAACTTTCTGAGCCTCTGT TTCTTCATTTTACAGTGTGGACACCTCCCTACCTCAGGGTGGTCAGGATTAAATGAGATA ACCAATACAACTTGTGTGGGTCAGTGCCTGCAGTACAGTAAGTACCCAGTACCAGTGATC CACATCTCATAATTACTATGACTTGGCCTGGCACAGTGGCTCACGCTTGTAATCCCAGCG TGATTACTTTGGGAGGCCAAGGCGGGTGGATCACCTGAGGTCAGGACTTCAAGACCAGCC TGGCCAACATGGTGAAACCCCATCTCTACTAAAAATACAAAAATTAGCTGGGCGTGGTGG TGGGCGCCTGTAATTGCAGCTACTTGGGAGGCTGAGGCAGGAGAACCACTTGAACCCAGG AGGCGGAGGTTGCAGTGAGCTGAGATTGCACCATTGCACTCCAGCCTGGGCAATAAGAGG GAAACTCCATCTCAAAAAATAATAATAATAATTACGATGACTTGTCCAAGGAGAAAACTG GAAGCCTTGGGGCTCACTGCCACTCTGCTCACTCACCACCACCAGTTTTTGTGTTTCTGG CTGACTTCAGTGCCTTCATCTCCCTTCCACAGAGCATCTCCTTTACCCCACCTCAGCTGC CCACTCCCATGGTAATACCTGCATCTTGTCACTTCACAGCTCCAAAGCCTCAATTCCAAG CACCCCTCTCTGCCCTGACAACTCATCTTTCCAGCTCACTTACTCTGGTTACTCCATGCC AGTAAGTCTTTGACCCCTGACCTTAACACAGTAACACTATGCAATACCCAACTCGTGTCC TCAATTTCCTTCTTACTTGACTCAGATTTCATGATCCAGCTCCTCAGCCAGGGCCGTTCA CAGACCTGGAACTCCCTGGTCCCACTTCTCCCCTCTATCTTACTCACCTGGCAAAATCCC AACCCTGTAAAATCCAGCTCTGCCCATTCAGCACTGCTCCTGGGCAGCTGACTGTGGCTA AGAAAAGATGTACCACTGTGCTCACTCTTTACAACACATGCAAGTATCTAGGAGGAAGGG AGGGAAGGAGGGAGAAAAAAGTTCTCCTTTGACGACCACCACCAGACCTAGTTCTCTGTC CGCTTTGCAGGAAAACTCCTTAAAAGACTTACCTACTTTTTTCACCATTTCTTCCTGCTA TCTTCTTTGTAACTGTAAACTACAACATACAAAAAAATGCACAGAACATACATGTGCAGC CTGATGAACCCCATACCACCCAATGTGTGACAACATGTTCCATCTGTCCTTGTTTTTTTT TGTTTTTGTTTTTGAGACAGAGTCTCACTCCCTCACCCGGGCTGGAGTGCAGTGGTGCGA TGTTGGCTCACTACAACCTCATCCTCCCAGGTTCAAGCGATTCTCGTGCCTCAACCTCCT GAGTAGCTGAGACCACAGGCGTGCGGCTCCACACCTGGCTAACTTTTTGTATTTTTAGTA GAGATAGGGTTTTGCCATGTTGGCCAGGCTGGTCTCAAACTCCTGACCTCAAGTAATGCG CCTGCCTCAGCCTCCCAAAGTGCTAGGATTACAGGGATGAGCCACCATACCGGCCGCCAC TCATCCTTCTTGATCATAATCCTCTCCCTCTATACATGCAAGCTTTATCCTTTTAAGGAA ATCAACTCCTTACATTTCTCTTTAGTTTATGACCTGTGTATCTCTCAACAATGCAGCTTA ATTTTGCAGCTTTCAAACTTGATAGAACTGAAATTGTGCAGTATGGATGCTATTGGGTCA GACTCTTTTCACACAATGTTATGTGAAGTTGTTGCACCTTCTCTCATGGGCCTACTCCAG TTTGGCTTTCTCCACCCCACTGAAACCACGGATCTTCACATTGCCAAGCCTGCTGAGCAG CTCTCTGTTCTCTCATTTGGCCTGTCAGCAACAGTTGACACAGCTGATTCCTCCTTTCCT CTTCAAACACCTTCTTCATTTGACTTCTGGGACGCTCCCTTGGTTTTCCTCCTTCTCACT GTCCTTTGCCCAACTAAATGCTGGCTTGTCCTAAGGCTCAGTCCTTGACCTCCTCTTCTC CAACTATTTCCTTTCTCTCCTACATCTCATCCAATTCCATGGCTTTTTTTTTTTTTTTTT TGACGAAGTCTTGCTCTGTCACCCAGGCTGGAGTGCAGTGGTATGATCTTGGCTCACCGT AACCTCCGCCTCCAGGATTCAAGCAATTCTCCTGCCTCACCCTCCTGAGTATCTGGGACT ACAGGCACGCACCACCACACACGGCTAATTTTCTGTATTTTTTGGTAGAGACAGGGTTTC ACCATGTTGGCCAGGCTGGTCTCAAACTCCTGGCCTCAAGTGATCCACCTGCCTCAGCCT CCCAAAGGGCTGGGATTATAGGCATGAGCCACTGTGCCCAGCCTAATCCTGTGGCTTTAA ATACCACTTATATCCATCAATGGTTCCCCAAATTTAAATCTTTCCCAAATTCAAATTTCC GTCCTCTTCTCTCCCCTAAGCTGCTGACTACTTACCCACTGCCTATTCAACATCTCCACT AGGGATATTTAAAAAGAATCTGAAATTTCATTTCTGATTCCCCTCTCCTCCCCAAAGCCT TCAAATCTGCTTCTCCCCCAGTCTTCCCATCTCAGTATTTCCAGTTGCTCAAGACAAAAA CCTGGAAGTCCTTCTTTATCCTCACTTTCCTTCACGTGCCAACTGCAAGCCATCAGCGAT CTCATTTTCTCTACCTTCAAAATATATCATGCTTCCGGCCCTGTCTCACCACCTCCAGCT CCAGCATCCTACTCTAAGCAACTCTTATTTCTCTCCTAGATTACTGAAATAGCCTCAACT GCTCTCTCTGCTCCCTTTCTTGCCCACCCCCCATCATTTATTCTCTACTCAGGAGGTAAA CTTATAAGAAACAAAATCAGATCCTATCATTCCCCTGTTCAAAACCTACCCTTGGCTTCT CATGAGACTTGGAATAAAATCCAAAATGGCTGTCACAGCCTCAGGGCTCTACATGATGTG GGCCCTGGTGATCTTGCTGACCTCATCCCCAGTACTTTATCCTGGCTCCCATACTCCAAT CCCCTGGGCACTCTTGCTGGTCCTAGAATCTCCAAGCCCATTCCCTCCTCAAGACCCTTT CCCCACAGTTCTGAATGGCTCACTTCATCTCATCATCCAGTTCTCTCCTCAGGGAGGTTT TCCCTGAGCACCTCTCCTCTCAGTCACTCTCTATCCCCTTTCATTGCTTTATTGCCTTCA CTGCCCCTACATGATTTCGGATCACAAAATCTATTTACTCACAAGAAAATAAGCTCCATG AATCTACAGACCTTTTTGCCATTTCCACAGCAGTATGTCCCATCCCTAGAATATCTGGCA CCTGGTTAAGTGTTCAGTACATATTTGTTGAATGGGTAAATGAATGAGAGCTGGAGGGAA ATCCAAACTCAGGGGTGCCTGTGCCACAGCAAACACTCTCCCTCTCACACCACCTGGAAT AGAGATCAGCTAGAGCAGAGGCTGCTAAGAGAGGGAACAGAGGCTCCTTGTGACAGGGAG ACTAGGATCAGAAGTCAGGGAAGGGACAGCCGGGTGAAATGACTGGAAAGAGGAGCAATC ACTCAGCAGTAAGGCAGGTTCTTCCAAAGACAAAAAGGACACAGAGATAAGTCAGGGCAC TTCCAAGGAACCCAACTACCTACTCCACACTCCCAAATTTATTCTGGGTTGGGCCCTTTT TGGTTCCAATATCACCTCGGATACCATAACTTGTCCAAGGTCTCTTCTTACCTCTCCCAC CCTAAATGAAGACGGGCCCTGGGTCCTAATCATACATTCCTTTTTCCTCCACTGTGAGCT GAGACAAAGCCCTTAAGAGGAGATTCTCCTTGGCAACAAACTTAAAGGGTTAAAACCTAG AAGAATACTAATTCTTGCTGAGCTCCTACTATGATTTGATAATCACTGTACTACAGACTA ATTACTACAATTCAAATGGTTTATATAAACCACTTAAAACAGTGCCTGTTACATAGTAAG CACCATATAAATACTGAGTTTTAACAATAATAATTGTTATTATTGTTATCACTATTTGTC AGGCATTCTTACACTCTCTTAACACTATTCCCATCATTCCTCACATCCATTCTTTTTTTT TAAAGACAGGGTCTCTATCAGCCAGGCTGGAGTGCAGTGGCACAATCATAGCTCACTGCA GCCTTGAACTCTTGGGCTCAAGTGATCCTCCTGCCTCAGCCTCTGAAGTAGCAGAGACTA CAGGCACATACCACCACACTTGGCTAGTTTTCTTTATCTTTTGTAAAGATGGGGTTTCAC TATGTTGCCCACACTAGTCTTGAGCTCCTGGTCTCAAGCAATCCTCCCACCTCAGCCTCC CAAAGCGCTGGGACTATATAGGCATGAGCCCTCACACATGGCCGTCATCCATTCTTTTAC TCAGGTATCAATGTCCTTATTTTTAAAATCAAAGTAACTAAGACTCAGAGTAGCAAAATC ACTTACTCAAGACCTCACAGCTGAGAAGAGGTGGAATTTAACTCAGGCTGTCATGATCCT TCCACTGCAGCAGACGCCTCTTCTGCCTTGCCCACCGCCACTGGCAGAGATCACCCCTCA GACACCCTGGGGCCTAATGAGACCTGATCGCCCTCTCTCTTCTCCGAATATGAAAACTCT GTACCTCCTTGGAGGCCACCACGCACAAGCTGCCACTTCCTTACCCACACAGCCGATGGT CACCACCCCATCCTTGTAGCGCTCTTGGGTTGGGCCAGTTGGCTCCATTGCTGAATCAGT CTGCTGCTCCACCAGGACTGCTGGGCCATCCTCCTCTTCCTCCTCCTCCCCAGAGCCATT ACCCCAGGTGGCCCCAGCCACATCCCGAGCAATCTTCTCCCGCCAGCTGCTCAAGTCCAC TGCTCAAAGAAGGAGAAGATTAAAGAGGTTCTCCCCAGGGCTGCTGTGCATGATGGCACA TACTGTGCCCTGCACAGATTATGTAACTGGCACCCTCTGGAGTTGTACAGTGCCAACCTA AATAAGAGCAGGTCAGAGAATCTCCCAAAAGTCATTTGACCCTACCCTCCCTGGAATCAC GCACGTTTCTCTGAGCTTCTGAAAAGTACTGGGAAGGCTAAAGGCAGCAAGCCACTGAGG CTCCTGACTACCTGCTGCCTCTCGTCCCACCAAGTCAGTCTGCTCCTTATTCTGTCCCTT CCCCTGGCCTCTTGCACATATCCACCATAGAGGGGTTGGCTTCAGGAAAGGTGAGCAAAA TGATTCTGCATCTTTGGTCTCCCCCATGTCCTCCTACAGCCCTCCTCTAAGGGCCACATA CCTTTCCCCACAGTGATGGCTTCACAGGCTCTCAGCAACTGCTCTGGCCCCAGGGCCCGA GTCCATCCTCTCCCCCGCCTCCGACTCTTCTTCAAGACTGAGATCAGAGGGCACAAAAGG ATGGGCACACGGGCTTAGGCCTCTCATCTCTCCCACCACCCTTAGGCCCAAGACCAGGTG CCCCCTTGTCAATAAGCCTCTCTGTTCTCCCCTTTGTCCCCTGCCAACTCACCTCTCCCA AGTTGCCCTCTCTCATTGCCCACTCACCACTACTAGGATCCTGTGGGGTGCGGGGGTCCC GAGGAAAAGAGGTGAAAAGGACGACGTGGAGCTGGGGATAGTGTTGATGGAAATAATGCT TCCAGGCAACCACAAGAGCTGGCGGGGCCAGATCCACCTTGTTCAAAACCAGCACCAGGG CCAGTCCAAGTTCTCCAGTCACATACTCATAAAGTGCTGGCGGGAAATTCACAACCTAGG ACAGAGTTGATAAGAGGATGGAGCACTGAAAGTCAACCCAGAGTTCTCTGCCTCCAGCTC CCCACTCAGCAGGTGTAGCTCAGAGACAAGGCCCTGGTGGTAGCAGACTCTGGGCTAAAA ACTATAAACCAGACAAACTGAAAAACAAAGACAAAACAGGGGTTAGTAATACTTCTGAGT CTCAGAGGGCTTCCTATAGGTCATGATTAGAGATGGAAATGAACCCAAAACAAGACAAGG AAACAGCATCACTTAGCACACTGAGGTAAAGGCTGGGATCGGAAACAGGGATGGGGGTTA GGGTAGAAATTAGTCTGCTTTTTTGTGTGTGCACAACTATGTAAGTGTGTACACGTGCAT ATATGCATGCATGCAAGTACGTGCACATGTGTGCATGTTTGTGTGTTAATGTGACTGTGA ACATGTGTGCAAACATGCCTGTGTATATTGATGTGCACATGATGTACGTGTGAGTATGTG TGTGTACATATTATTAAGGACCTCCAACCTAAATGGTCCTCACAGACCTCCCTTTCTCCC ACTGGAGGACAAGAGTGAAGTTGCAGAGCTAGGATTCACACAGGGCAGTCCAGCAGCAGT CTACAGCCTTAACTACTACTCTAGCATTCCAGGTGGGTTCTGTAGCAACTGATGTGGCAG TGCTAGAGAAATGAGATAAGGAAGAAAGGGCATCTTTGGGCTGGGCAGGAGGAAGTCCCC AGCTGCATTCATAGAATCCCTGGAGCTCCAACACTTGGATTTTCTATTGGTCTGTGATGA GCTAAAGGACAGGACATGGCTGTTTTGAAGAGAAGAGTGAGCTGGCCAAGGGAGGAATGA CAGGCTATAAGAGAATAAAAAACTGAGTTCCTAACTGCGGACATCAGCACTAGGTAGAGA TTAGAAAGACAGGAAGATAGATACCTCTCTGTCTCCCAACTCTTGCCTCTGACCTTTGCC CCTGAAAAACCTTTCTCCCTCCTCCTTGCCCACCCTTATCCCTAGTACTCACTGGATGTC GGATATCAGTGATAAGCAGGACGATGTCAGACATCTCTAACACCCGCCACAGCTGCCTCC ATGTCTAAAAAGACAGGATCAGGAAGAGAAACTGAAAACAGAGTCCCTCTCCAGCCTGAT CCCAAACCAATTTGACCATAGGTCACTATGCCCCACTCCTGTCCCTAGAGTACACTGTCA CCTCCAGATTGTGCTCAAAGTAGCTGAGTTTCTCAGAGGAGTAAGCCCCATGAATCTTCC CAAGATAGTCTTGGAAGCTCCGTTCCTCTTGGCTCATTAGTTGCTCCTTGGACATCTCAT AGCTCCAAGGAGGACGTCGAGGAAAGTCCAGAACTGGGAATTCAGGAAAAAGTCCAAGTG TGAGGAAATCTTCAGGATTCAAGAGTACATCCCAGACCCCTCCTTCCTCACAGTCGGCTT TTACCTTTCCAAACTCCTTCCCCAGCCCAATGCCTGTCTTGCTCTCACTCACCTGAGCCA GGCTGATACACCTCCCGGATGTCCAGCTCCAACAACTCAGCACTGACCGGCTGTAGAACT TGCTCCCGGGCTGCTCTCTTTCTCCTCTCTACCTCCTCCCTGCTGTCTCTCTCAAAATGC AGTCGGTATCTAAGGGAACAGGGACCGAGACATCCAGAGCAATCCTGTGGCCACAAACTC CTATTTTCTCCCCTCTTGTACAATCAACTTCGCAAACCATTCTCTCCAGAGTCGTTCAAG TCTCCTCTCTCAAGTCAGACTTCCCCCAAGTCCTTCTTTCAGGCAATACTCAGCCTTCTC CTTCTAAAAGCCCAACTCTCTCCAGCCCCTCTGGAAAGGAAGACTGTGGCCCGCTGTGGG GAGCCGAGTGGCTAGCGGAGAACTGTGGCATCCCAGGCCCACCGTCTTCACCAGTAGCAG CCCGCTTTCCCCCAAAGCTCTGACTTCCGOGTAGGCGGGAAAGCCGGGACCAGCGCCCCC TCCCACCCTCACCGATTTGGGTCGTAGCCTCGTGGACCCAGCCCCTGAGAAGGCTGCTGG TTAAGCCTGCGGATATGATGGGTCACAGACTCCCCGTCCGAGGTGTCGGTCTGTTCCTCT CGCCGCTCCCGGCTCCCGCTGCGGCTGTTGGAACTGGAGCGCAGCCCATCTTGAAGCCCT GCGGGGAGCGGCCCGTGACGCCAGTGCTGGCCAGCTCTCAGGGGCCATAAGACCCTCTCC CCCATCGGCCTGACTCCCTTTCATCCCACTCAACTTCTTCCGATGTTCAGTCCTCCCAGA CACCCTATTTGGGACCCTCCCGGATGTGCGTGGGGGGAGTCACTCCTTCAGGGAGCAGTG GGGACGGCGCCCCGTGCTAGCTGGAGGGATTCCCCTCCCCCAACTCTCCATCCTTCCCCA CCCCTTCCAGATGTAGGGGGGGTGGGGGATCCCCTCCGCGATAGGCCGCGAGGGTTGACG CGGTCCCACGACCCCCTCCCACGATCCCCAGAGGTGCAGCCGGCACACCCCTCCTTCCAG ATGTGCGGAAGCCCGAGCCCCGCCCCCTCCTCCCGCTCCCGCACTGACCTCTCTTCCGCT CCCGTTTGTCCTGCAACTGCTTCTTCTTCTGCTTCACGCTGAATGGCTTCTTCCTCGGCA T

The resultant PCR product from primer set 2 has 5′ overhangs at both ends: one end comprising the overhanging sequence 5′TTTn, and the other end comprising the overhanging sequence 5′CCCn (where n is an abasic nucleoside). The double-stranded portion of the PCR product comprises the following sequence:

TGGAACAGCCGCTCTCACCTCAGTTCATCTGGGGAAGGGGCTACAAAGCAAACAATCTTT (SEQ ID NO: 6) ATTCACAATTGGGGTGGCAGAGGGGAGATACCCCCAGGTCAGTCCAAAAGCAAAGATACT GGGAGGGAAGATGGCGCTGGGCGAGGAACTCAGCACTCATCCTCACCCAGCAGGGCATAA GGGTTTCGGCCAGCCAGGCTGGACCCTGGAGCCGAGGTTGGGGTCTCCTCATCCCCTTCT CCCTCCTCATCCGCATCCCGGTCCTCCTCTCCCTCCTCCTCACAGGAGCTGCTCAGCTCT TCCTCTTCCTCCTCCTCCTCGTCACCTGCTGGCCCCACCCTGCCCTGCAAAACCACCAGC TCCGTGGTCTCTGGATGGGACTCCCAGGTGCCTGGGGAACCAAAACAAGAAAAAAATGGA GGAGAGTTTTGAGCAAGAACTAAAGCCAAGGAAAGATGGGGAAGAGGCAAAGACTAGGAA TAACAATAATCTTTAGAGCTGCTGGCATTCATTCATTCATCCATTCATTCAACTTCCTAT GTGCAGATTGCTGAACAGAACCTTTGTGCACATCAACTTCAATCTTTACAATCACTATGC TAAGGGTCAATTATTACCCTCAGTTTGCAGATCAGGAAAATATCACAGATGTTAAGTAAC AGAGCTAGCCAACAGGTACAGAATCCAGGTTTGACCCTCTCTCTGGCCACAAAGCCCACA CCCTTTTACCTACGCTATAGCAGGGGGCTGGGGAAGAATATCTGGGCTCTGACCTTTCTG TTCACTGTAGCCTGGGGGATGAAAACACAGGCTGAGGCGGCCGTCCACTGCCAGCCGCAA GAGACTGTTGGCTGCTCTGTACACATCATTCCGAGCCGCCTTGGCTGTCTTGTAACCACG TTTCTCTGCCCAGGCTGGAGGAAGAAAAGAATAATGGAAAGGGAAAGCATTAACCAGGTA CCAGTTATACTCCCACTCCCATAACACAGTCCTTCCAGTTTTCCCCAAAACATTCCAGGC CAGAGATCTTACTGGCTATGCAACAAAAATCTAGGGGTGAGTGGACAGCAGCTTCATCAA TGGCAGAATCTCTGAGGAGAGGAAAGGAGACAGGGAAGGGTAAAAGGCGAGGCAGGTAAG GAAGAGCAGCTGAAACCAGGTGGGGCGAAGCCAGGCACATGGAACTCACCTTCACAGATG TCCCAGGCACACCAGGGGTGTTCCGCTGAGGGGTCCTCAGCCTCTGGGTGGCGCAGGTGG AGCAGGGCCTGCACGGGAATTCGGGAGGCCAGGTAGCCCACAGCAGTGTAGGGCTCCTGG ATCTGGGCGATAGGGTAGATCCCCGCCAGAACCTGAGGGAAATGAGCACTCAGTACTTTC CTCAATGTCCCACCTTCTCTCTTTCCCTTACCCACCCTCCCCGTCATACCTGCAACTGCC TAGGCAGAAGAGATGGGAAGATGAGGCCTGGGCAGTCACAGAGCTTCACAGAGGGGGTAA GAAAGTAGGTCTGAAAGTATCGGGTATGGCCCGGGGTTCTGGAGACACTCACGACTTTCC GCCCCACCAGCCCATTGATCAGCGAGGACTTTCCCACATTAGGGAAACCTGAGGAAGGCA AGGAAAATTAACGTTTAACAGGTTTCTACTCTGTGATGGGACTTGGTGCTATACCTATAG GTAAAAGGGGAACTAAGGCTCAGAAATTAAGGAAATGGTATTGCAGAATACAAATCACGC TCTGGGCTGCCAGGGTTAAATCCTGGCCCTTCCACTTACCAGCTTTGTGATGTCAGGGCA ACTAACTTTCTGAGCCTCTGTTTCTTCATTTTACAGTGTGGACACCTCCCTACCTCAGGG TGGTCAGGATTAAATGAGATAACCAATACAACTTGTGTGGGTCAGTGCCTGCAGTACAGT AAGTACCCAGTACCAGTGATCCACATCTCATAATTACTATGACTTGGCCTGGCACAGTGG CTCACGCTTGTAATCCCAGCGTGATTACTTTGGGAGGCCAAGGCGGGTGGATCACCTGAG GTCAGGACTTCAAGACCAGCCTGGCCAACATGGTGAAACCCCATCTCTACTAAAAATACA AAAATTAGCTGGGCGTGGTGGTGGGCGCCTGTAATTGCAGCTACTTGGGAGGCTGAGGCA GGAGAACCACTTGAACCCAGGAGGCGGAGGTTGCAGTGAGCTGAGATTGCACCATTGCAC TCCAGCCTGGGCAATAAGAGGGAAACTCCATCTCAAAAAATAATAATAATAATTACGATG ACTTGTCCAAGGAGAAAACTGGAAGCCTTGGGGCTCACTGCCACTCTGCTCACTCACCAC CACCAGTTTTTGTGTTTCTGGCTGACTTCAGTGCCTTCATCTCCCTTCCACAGAGCATCT CCTTTACCCCACCTCAGCTGCCCACTCCCATGGTAATACCTGCATCTTGTCACTTCACAG CTCCAAAGCCTCAATTCCAAGCACCCCTCTCTGCCCTGACAACTCATCTTTCCAGCTCAC TTACTCTGGTTACTCCATGCCAGTAAGTCTTTGACCCCTGACCTTAACACAGTAACACTA TGCAATACCCAACTCGTGTCCTCAATTTCCTTCTTACTTGACTCAGATTTCATGATCCAG CTCCTCAGCCAGGGCCGTTCACAGACCTGGAACTCCCTGGTCCCACTTCTCCCCTCTATC TTACTCACCTGGCAAAATCCCAACCCTGTAAAATCCAGCTCTGCCCATTCAGCACTGCTC CTGGGCAGCTGACTGTGGCTAAGAAAAGATGTACCACTGTGCTCACTCTTTACAACACAT GCAAGTATCTAGGAGGAAGGGAGGGAAGGAGGGAGAAAAAAGTTCTCCTTTGACGACCAC CACCAGACCTAGTTCTCTGTCCGCTTTGCAGGAAAACTCCTTAAAAGACTTACCTACTTT TTTCACCATTTCTTCCTGCTATCTTCTTTGTAACTGTAAACTACAACATACAAAAAAATG CACAGAACATACATGTGCAGCCTGATGAACCCCATACCACCCAATGTGTGACAACATGTT CCATCTGTCCTTGTTTTTTTTTGTTTTTGTTTTTGAGACAGAGTCTCACTCCCTCACCCG GGCTGGAGTGCAGTGGTGCGATGTTGGCTCACTACAACCTCATCCTCCCAGGTTCAAGCG ATTCTCGTGCCTCAACCTCCTGAGTAGCTGAGACCACAGGCGTGCGGCTCCACACCTGGC TAACTTTTTGTATTTTTAGTAGAGATAGGGTTTTGCCATGTTGGCCAGGCTGGTCTCAAA CTCCTGACCTCAAGTAATGCGCCTGCCTCAGCCTCCCAAAGTGCTAGGATTACAGGGATG AGCCACCATACCGGCCGCCACTCATCCTTCTTGATCATAATCCTCTCCCTCTATACATGC AAGCTTTATCCTTTTAAGGAAATCAACTCCTTACATTTCTCTTTAGTTTATGACCTGTGT ATCTCTCAACAATGCAGCTTAATTTTGCAGCTTTCAAACTTGATAGAACTGAAATTGTGC AGTATGGATGCTATTGGGTCAGACTCTTTTCACACAATGTTATGTGAAGTTGTTGCACCT TCTCTCATGGGCCTACTCCAGTTTGGCTTTCTCCACCCCACTGAAACCACGGATCTTCAC ATTGCCAAGCCTGCTGAGCAGCTCTCTGTTCTCTCATTTGGCCTGTCAGCAACAGTTGAC ACAGCTGATTCCTCCTTTCCTCTTCAAACACCTTCTTCATTTGACTTCTGGGACGCTCCC TTGGTTTTCCTCCTTCTCACTGTCCTTTGCCCAACTAAATGCTGGCTTGTCCTAAGGCTC AGTCCTTGACCTCCTCTTCTCCAACTATTTCCTTTCTCTCCTACATCTCATCCAATTCCA TGGCTTTTTTTTTTTTTTTTTTGACGAAGTCTTGCTCTGTCACCCAGGCTGGAGTGCAGT GGTATGATCTTGGCTCACCGTAACCTCCGCCTCCAGGATTCAAGCAATTCTCCTGCCTCA CCCTCCTGAGTATCTGGGACTACAGGCACGCACCACCACACACGGCTAATTTTCTGTATT TTTTGGTAGAGACAGGGTTTCACCATGTTGGCCAGGCTGGTCTCAAACTCCTGGCCTCAA GTGATCCACCTGCCTCAGCCTCCCAAAGGGCTGGGATTATAGGCATGAGCCACTGTGCCC AGCCTAATCCTGTGGCTTTAAATACCACTTATATCCATCAATGGTTCCCCAAATTTAAAT CTTTCCCAAATTCAAATTTCCGTCCTCTTCTCTCCCCTAAGCTGCTGACTACTTACCCAC TGCCTATTCAACATCTCCACTAGGGATATTTAAAAAGAATCTGAAATTTCATTTCTGATT CCCCTCTCCTCCCCAAAGCCTTCAAATCTGCTTCTCCCCCAGTCTTCCCATCTCAGTATT TCCAGTTGCTCAAGACAAAAACCTGGAAGTCCTTCTTTATCCTCACTTTCCTTCACGTGC CAACTGCAAGCCATCAGCGATCTCATTTTCTCTACCTTCAAAATATATCATGCTTCCGGC CCTGTCTCACCACCTCCAGCTCCAGCATCCTACTCTAAGCAACTCTTATTTCTCTCCTAG ATTACTGAAATAGCCTCAACTGCTCTCTCTGCTCCCTTTCTTGCCCACCCCCCATCATTT ATTCTCTACTCAGGAGGTAAACTTATAAGAAACAAAATCAGATCCTATCATTCCCCTGTT CAAAACCTACCCTTGGCTTCTCATGAGACTTGGAAATAAATCCAAAATGGCTGTCACAGC CTCAGGGCTCTACATGATGTGGGCCCTGGTGATCTTGCTGACCTCATCCCCAGTACTTTA TCCTGGCTCCCATACTCCAATCCCCTGGGCACTCTTGCTGGTCCTAGAATCTCCAAGCCC ATTCCCTCCTCAAGACCCTTTCCCCACAGTTCTGAATGGCTCACTTCATCTCATCATCCA GTTCTCTCCTCAGGGAGGTTTTCCCTGAGCACCTCTCCTCTCAGTCACTCTCTATCCCCT TTCATTGCTTTATTGCCTTCACTGCCCCTACATGATTTCGGATCACAAAATCTATTTACT CACAAGAAAATAAGCTCCATGAATCTACAGACCTTTTTGCCATTTCCACAGCAGTATGTC CCATCCCTAGAATATCTGGCACCTGGTTAAGTGTTCAGTACATATTTGTTGAATGGGTAA ATGAATGAGAGCTGGAGGGAAATCCAAACTCAGGGGTGCCTGTGCCACAGCAAACACTCT CCCTCTCACACCACCTGGAATAGAGATCAGCTAGAGCAGAGGCTGCTAAGAGAGGGAACA GAGGCTCCTTGTGACAGGGAGACTAGGATCAGAAGTCAGGGAAGGGACAGCCGGGTGAAA TGACTGGAAAGAGGAGCAATCACTCAGCAGTAAGGCAGGTTCTTCCAAAGACAAAAAGGA CACAGAGATAAGTCAGGGCACTTCCAAGGAACCCAACTACCTACTCCACACTCCCAAATT TATTCTGGGTTGGGCCCTTTTTGGTTCCAATATCACCTCGGATACCATAACTTGTCCAAG GTCTCTTCTTACCTCTCCCACCCTAAATGAAGACGGGCCCTGGGTCCTAATCATACATTC CTTTTTCCTCCACTGTGAGCTGAGACAAAGCCCTTAAGAGGAGATTCTCCTTGGCAACAA ACTTAAAGGGTTAAAACCTAGAAGAATACTAATTCTTGCTGAGCTCCTACTATGATTTGA TAATCACTGTACTACAGACTAATTACTACAATTCAAATGGTTTATATAAACCACTTAAAA CAGTGCCTGTTACATAGTAAGCACCATATAAATACTGAGTTTTAACAATAATAATTGTTA TTATTGTTATCACTATTTGTCAGGCATTCTTACACTCTCTTAACACTATTCCCATCATTC CTCACATCCATTCTTTTTTTTTAAAGACAGGGTCTCTATCAGCCAGGCTGGAGTGCAGTG GCACAATCATAGCTCACTGCAGCCTTGAACTCTTGGGCTCAAGTGATCCTCCTGCCTCAG CCTCTGAAGTAGCAGAGACTACAGGCACATACCACCACACTTGGCTAGTTTTCTTTATCT TTTGTAAAGATGGGGTTTCACTATGTTGCCCACACTAGTCTTGAGCTCCTGGTCTCAAGC AATCCTCCCACCTCAGCCTCCCAAAGCGCTGGGACTATATAGGCATGAGCCCTCACACAT GGCCGTCATCCATTCTTTTACTCAGGTATCAATGTCCTTATTTTTAAAATCAAAGTAACT AAGACTCAGAGTAGCAAAATCACTTACTCAAGACCTCACAGCTGAGAAGAGGTGGAATTT AACTCAGGCTGTCATGATCCTTCCACTGCAGCAGACGCCTCTTCTGCCTTGCCCACCGCC ACTGGCAGAGATCACCCCTCAGACACCCTGGGGCCTAATGAGACCTGATCGCCCTCTCTC TTCTCCGAATATGAAAACTCTGTACCTCCTTGGAGGCCACCACGCACAAGCTGCCACTTC CTTACCCACACAGCCGATGGTCACCACCCCATCCTTGTAGCGCTCTTGGGTTGGGCCAGT TGGCTCCATTGCTGAATCAGTCTGCTGCTCCACCAGGACTGCTGGGCCATCCTCCTCTTC CTCCTCCTCCCCAGAGCCATTACCCCAGGTGGCCCCAGCCACATCCCGAGCAATCTTCTC CCGCCAGCTGCTCAAGTCCACTGCTCAAAGAAGGAGAAGATTAAAGAGGTTCTCCCCAGG GCTGCTGTGCATGATGGCACATACTGTGCCCTGCACAGATTATGTAACTGGCACCCTCTG GAGTTGTACAGTGCCAACCTAAATAAGAGCAGGTCAGAGAATCTCCCAAAAGTCATTTGA CCCTACCCTCCCTGGAATCACGCACGTTTCTCTGAGCTTCTGAAAAGTACTGGGAAGGCT AAAGGCAGCAAGCCACTGAGGCTCCTGACTACCTGCTGCCTCTCGTCCCACCAAGTCAGT CTGCTCCTTATTCTGTCCCTTCCCCTGGCCTCTTGCACATATCCACCATAGAGGGGTTGG CTTCAGGAAAGGTGAGCAAAATGATTCTGCATCTTTGGTCTCCCCCATGTCCTCCTACAG CCCTCCTCTAAGGGCCACATACCTTTCCCCACAGTGATGGCTTCACAGGCTCTCAGCAAC TGCTCTGGCCCCAGGGCCCGAGTCCATCCTCTCCCCCGCCTCCGACTCTTCTTCAAGACT GAGATCAGAGGGCACAAAAGGATGGGCACACGGGCTTAGGCCTCTCATCTCTCCCACCAC CCTTAGGCCCAAGACCAGGTGCCCCCTTGTCAATAAGCCTCTCTGTTCTCCCCTTTGTCC CCTGCCAACTCACCTCTCCCAAGTTGCCCTCTCTCATTGCCCACTCACCACTACTAGGAT CCTGTGGGGTGCGGGGGTCCCGAGGAAAAGAGGTGAAAAGGACGACGTGGAGCTGGGGAT AGTGTTGATGGAAATAATGCTTCCAGGCAACCACAAGAGCTGGCGGGGCCAGATCCACCT TGTTCAAAACCAGCACCAGGGCCAGTCCAAGTTCTCCAGTCACATACTCATAAAGTGCTG GCGGGAAATTCACAACCTAGGACAGAGTTGATAAGAGGATGGAGCAGTGAAAGTCAACCC AGAGTTCTCTGCCTCCAGCTCCCCACTCAGCAGGTGTAGCTCAGAGACAAGGCCCTGGTG GTAGCAGACTCTGGGCTAAAAACTATAAACCAGACAAACTGAAAAACAAAGACAAAACAG GGGTTAGTAATACTTCTGAGTCTCAGAGGGCTTCCTATAGGTCATGATTAGAGATGGAAA TGAACCCAAAACAAGACAAGGAAACAGCATCACTTAGCACACTGAGGTAAAGGCTGGGAT CGGAAACAGGGATGGGGGTTAGGGTAGAAATTAGTCTGCTTTTTTGTGTGTGCACAACTA TGTAAGTGTGTACACGTGCATATATGCATGCATGCAAGTACGTGCACATGTGTGCATGTT TGTGTGTTAATGTGACTGTGAACATGTGTGCAAACATGCCTGTGTATATTGATGTGCACA TGATGTACGTGTGAGTATGTGTGTGTACATATTATTAAGGACCTCCAACCTAAATGGTCC TCACAGACCTCCCTTTCTCCCACTGGAGGACAAGAGTGAAGTTGCAGAGCTAGGATTCAC ACAGGGCAGTCCAGCAGCAGTCTACAGCCTTAACTACTACTCTAGCATTCCAGGTGGGTT CTGTAGCAACTGATGTGGCAGTGCTAGAGAAATGAGATAAGGAAGAAAGGGCATCTTTGG GCTGGGCAGGAGGAAGTCCCCAGCTGCATTCATAGAATCCCTGGAGCTCCAACACTTGGA TTTTCTATTGGTCTGTGATGAGCTAAAGGACAGGACATGGCTGTTTTGAAGAGAAGAGTG AGCTGGCCAAGGGAGGAATGACAGGCTATAAGAGAATAAAAAACTGAGTTCCTAACTGCG GACATCAGCACTAGGTAGAGATTAGAAAGACAGGAAGATAGATACCTCTCTGTCTCCCAA CTCTTGCCTCTGACCTTTGCCCCTGAAAAACCTTTCTCCCTCCTCCTTGCCCACCCTTAT CCCTAGTACTCACTGGATGTCGGATATCAGTGATAAGCAGGACGATGTCAGACATCTCTA ACACCCGCCACAGCTGCCTCCATGTCTAAAAAGACAGGATCAGGAAGAGAAACTGAAAAC AGAGTCCCTCTCCAGCCTGATCCCAAACCAATTTGACCATAGGTCACTATGCCCCACTCC TGTCCCTAGAGTACACTGTCACCTCCAGATTGTGCTCAAAGTAGCTGAGTTTCTCAGAGG AGTAAGCCCCATGAATCTTCCCAAGATAGTCTTGGAAGCTCCGTTCCTCTTGGCTCATTA GTTGCTCCTTGGACATCTCATAGCTCCAAGGAGGACGTCGAGGAAAGTCCAGAACTGGGA ATTCAGGAAAAAGTCCAAGTGTGAGGAAATCTTCAGGATTCAAGAGTACATCCCAGACCC CTCCTTCCTCACAGTCGGCTTTTACCTTTCCAAACTCCTTCCCCAGCCCAATGCCTGTCT TGCTCTCACTCACCTGAGCCAGGCTGATACACCTCCCGGATGTCCAGCTCCAACAACTCA GCACTGACCGGCTGTAGAACTTGCTCCCGGGCTGCTCTCTTTCTCCTCTCTACCTCCTCC CTGCTGTCTCTCTCAAAATGCAGTCGGTATCTAAGGGAACAGGGACCGAGACATCCAGAG CAATCCTGTGGCCACAAACTCCTATTTTCTCCCCTCTTGTACAATCAACTTCGCAAACCA TTCTCTCCAGAGTCGTTCAAGTCTCCTCTCTCAAGTCAGACTTCCCCCAAGTCCTTCTTT CAGGCAATACTCAGCCTTCTCCTTCTAAAAGCCCAACTCTCTCCAGCCCCTCTGGAAAGG AAGACTGTGGCCCGCTGTGGGGAGCCGAGTGGCTAGCGGAGAACTGTGGCATCCCAGGCC CACCGTCTTCACCAGTAGCAGCCCGCTTTCCCCCAAAGCTCTGACTTCCGGGTAGGCGGG AAAGCCGGGACCAGCGCCCCCTCCCACCCTCACCGATTTGGGTCGTAGCCTCGTGGACCC AGCCCCTGAGAAGGCTGCTGGTTAAGCCTGCGGATATGATGGGTCACAGACTCCCCGTCC GAGGTGTCGGTCTGTTCCTCTCGCCGCTCCCGGCTCCCGCTGCGGCTGTTGGAACTGGAG CGCAGCCCATCTTGAAGCCCTGCGGGGAGGGGCCGGTGACGCCAGTGCTGGCCAGCTCTC AGGGGCCATAAGACCCTCTCCCCCATCGGCCTGACTCCCTTTCATCCCACTCAACTTCTT CCGATGTTCAGTCCTCCCAGACACCCTATTTGGGACCCTCCCGGATGTGCGTGGGGGGAG TCACTCCTTCAGGGAGCAGTGGGGACGGCGCCCCGTGCTAGCTGGAGGGATTCCCCTCCC CCAACTCTCCATCCTTCCCCACCCCTTCCAGATGTAGGGGGGGTGGGGGATCCCCTCCGC GATAGGCCGCGAGGGTTGACGCGGTCCCACGACCCCCTCCCACGATCCCCAGAGGTGCAG CGGGCACACCCCTCCTTCCAGATGTGCGGAAGCCCGAGCCCCGCCCCCTCCTCCCGCTCC CGCACTGACCTCTCTTCCGCTCCCGTTTGTCCTGCAACTGCTTCTTCTTCTGCTTCACGC TGAATGGCTTCTTCCTCGGCATGGCCCGGACCAGTCACCTGGCCCGCCCTCCGCCGAGCT CCCGCCGCCTCAACTGACTGCCCCCCGGGGCAGCCCCCGCCGCAGGGGCCCGGGACCCTA GAGGAGGCGGGGCTAGCAGGTGACGTCAGCGGCCGGGCCCGACAGAATTACCGCCGCGGC GGCGATGGAAGGCGGACGGGGGAGATATAGTCACTTCCCTCCAGGA

Both PCR products were used to generate libraries of DNA fragments using the following protocol:

The DNA is first prepared for ligation to forked adapters by: fragmentation of the DNA by nebulisation, end repair of the DNA ends to make them blunt-ended and phosphorylation, then the addition of a single ‘A’ nucleotide onto the 3′ ends of the human DNA fragments. The ligation reaction is performed with the prepared fragmented DNA and adapters pre-formed by annealing ‘Oligo A’ and ‘Oligo B’ (sequences given below). The product of the reaction is isolated/purified from unligated adapter by gel electrophoresis. Finally, the product of the ligation reaction is subjected to cycles of PCR to selectively amplify ligated product that contains adapter at both ends of the fragments.

Materials and Methods

Nebulization

Materials:

-   -   Human RF I DNA (1 mg/ml) NEB #N3021L     -   Buffer (glycerol 53.1 ml, water 42.1 ml, 1 M TrisHCl pH7.5 3.7         ml, 0.5 M EDTA 1.1 ml)     -   Nebulizer Invitrogen (#K7025-05)     -   Qiagen columns PCR purification kit (#28104)         Mix: 25 μl (5 micrograms) of DNA     -   725 μl Buffer

Oligo A: 5′ACACTCTTTCCCTACACGACGCTCTTCCGATC-x-T (SEQ ID NO: 7) (x = phosphorothioate bond) Oligo B: 5′Phosphate-GATCGGAAGAGCTCGTATGCCGTCTTCTGCTTG (SEQ ID NO: 8) Procedure:

Chilled DNA solution was fragmented in the nebulizer on ice for 5 to 6 minutes under at least 32 psi of pressure. The recovered volume (usually somewhere between 400 and 600 μl) was split into 3 aliquots and purified with a Qiagen PCR-purification kit, but using only one column, and finally eluted in 30 μl of EB (Qiagen).

End-Repair

Materials:

-   -   T4 DNA Polymerase NEB #M0203S     -   10×NEB 2 buffer NEB #M7002S     -   10×BSA NEB #M9001S     -   dNTPs mix (10 mM each) NEB #N0447S     -   E. coli DNA Pol I large fragment (Klenow, NEB #M0210S)     -   T4 polynucleotide kinase NEB #M0201S     -   T4 PNK buffer NEB #M0201S     -   100 mM ATP     -   Qiagen columns PCR purification kit (#28104)

End repair mix was assembled as follows:

DNA 30 μl Water 12 μl 10xNEB2 5 μl 100xBSA 0.5 μl 10 mM dNTPs 2 μl T4 DNA pol (3 U/μl) 5 μl 50 μl total

The reaction was incubated for 15 min at room temperature, then 1 μl of E. coli DNA Pol I large fragment (Klenow) was added and the reaction incubated for a further 15 min at room temperature. The DNA was purified from enzymes, buffer, etc by loading the reaction mix on a Qiagen column, and finally eluting in 30 μl EB. The 5′ ends of the DNA were then phosphorylated using polynucleotide kinase as follows:

DNA 30 μl Water 9.5 μl 10xPNK buffer 5 μl 100 mM ATP 0.5 μl T4 PNK (10 U/μl) 5 μl 50 μl total

The reaction was incubated for 30 min at 37° C., then heat inactivated at 65° C. for 20 min. DNA was then purified from enzymes, buffer, etc by loading the reaction mix on a Qiagen column, finally eluting in 30 μl EB. Three separate tubes were pooled to give 90 μl total.

A-Tailing Reaction

Materials:

-   -   Taq DNA polymerase NEB #M0267L     -   10× thermopol buffer NEB #B9004S     -   1 mM dATP Amersham-Pharmacia #272050     -   Qiagen MinElute column PCR purification kit (#28004)

The following reaction mix was assembled:

DNA 30 μl 10x thermopol buffer 5 μl 1 mM dATP 10 μl Taq pol (5 U/μl) 3 μl ~50 μl total

The reaction was incubated for 30 min at 70° C., then the DNA purified from enzymes, buffer, etc by loading the reaction mix on a Qiagen MinElute column, and finally eluting in 10 μl EB.

Anneal Forked Adapter

Materials:

-   -   ‘Oligo A’ and ‘Oligo B’     -   50 mM Tris/50 mM NaCl pH7     -   PCR machine

100 μM Oligo A 20 μl 100 μm Oligo B 20 μl Tris/NaCl 10 μl 50 μl at 40 μM duplex in 10 mM Tris/10 mM NaCl pH 7.5

The adapter strands were annealed in a PCR machine programmed as follows:

Ramp at 0.5° C./sec to 97.5° C.

Hold at 97.5° C. for 150 sec

Then a step of 97.5° C. for 2 sec with a temperature drop of 0.1° C./cycle for 775 cycles

Ligation Reaction

Materials:

-   -   15 μM forked adapter     -   A-Tailed genomic DNA     -   Quick Ligase NEB #M2200L     -   Quick Ligase 2× buffer NEB #M2200L     -   PCR machine     -   Qiagen columns PCR purification kit (#28104)

Reaction mix was assembled as follows:

DNA 10 μl 2x buffer 25 μl 40 μM adapter 10 μl Quick Ligase 5 μl ~50 μl total

The reaction was incubated for 20 min at room temperature then the DNA purified from enzymes, buffer, etc by loading the reaction mix on a Qiagen column, and finally eluting in 30 μl EB.

Gel Purification

Materials:

-   -   Agarose Biorad #161-3101     -   100 base pair ladder NEB #N3231L     -   TAE     -   Loading buffer (50 mM Tris pH8, 40 mM EDTA, 40% w/v sucrose)     -   Ethidium bromide     -   Gel trays and tank. Electrophoresis unit

The entire sample from the purified ligation reaction was loaded into one lane of a 2% agarose gel containing ethidium bromide and run at 120V for 50 min. The gel was then viewed on a ‘White-light’ box and fragments from above 300 bp to at least 750 bp excised and purified with a Qiagen Gel purification kit, eluting in 30 μl EB. For large gel slices two minElute columns were used, eluting each in 15 μl EB and subsequently pooling the two eluates.

PCR Amplification

Materials:

-   -   Ligated DNA

PRIMER 1: AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGA (SEQ ID NO: 9) PRIMER 2: CAAGCAGAAGACGGCATACGA (SEQ ID NO: 10)

-   -   2× Jump Start RedTaq PCR mix Sigma (#P0982)     -   PCR machine     -   Qiagen MinElute columns Qiagen (#28004)

The purified ligated DNA was diluted 25 fold, then a PCR reaction mix prepared as follows:

DNA 1 μl 2x Hot Start Red Taq mix 25 μl 100 μM P5 0.5 μl 100 μM P7 0.5 μl Water 23 μl ~50 μl total

Primer P5: 5′-AATGATACGGCGACCACCGAGAAAAACGCCAGCAA (SEQ ID NO: 11) Primer P7: 5′-CAAGCAGAAGACGGCATACGATCCGACAGCTT (SEQ ID NO: 12)

Thermocycling was carried out in a PCR machine under the following conditions:

-   -   2 min@94° C.     -   [45 sec@94° C., 45 sec@65° C., 2 min@70° C.] 16 cycles     -   5 min@70° C.     -   Hold@4° C.

PCR products were purified from enzymes, buffer, etc on a Qiagen MinElute column, eluting in 10 μl EB. The resulting DNA 5′ and 3′ modified library is ready for amplification on a surface PCR platform.

Validation of 5′ and 3′ Modified Library

1 μl of the DNA 5′ and 3′ modified library was cloned into a plasmid vector and plated out on agar. Colonies were picked, miniprepped and the cloned inserts sequenced by conventional Sanger sequencing. The sequence data of the genomic inserts (excluding vector and adaptor sequences) obtained including the position of the insert in the PCR product was as follows:

Primer set 1 PCR product 5′ and 3′ modified library: Clone 1 Position in 2CR product = 7105-7413 CTCTTCTTCAAGACTGAGATCAGAGGGCACAAAAGGATGGGCACACGGGCTTAGGCCTCT (SEQ ID NO: 13) CATCTCTCCCACCACCCTTAGGCCCAAGACCAGGTGCCCCCTTGTCAATAAGCCTCTCTG TTCTCCCCTTTGTCCCCTGCCAACTCACCTCTCCCAAGTTGCCCTCTCTCATTGCCCACT CACCACTACTAGGATCCTGTGGGGTGCGGGGGTCCCGAGGAAAAGAGGTGAAAAGGACGA CGTGGAGCTGGGGATAGTGTTGATGGAAATAATGCTTCCAGGCAACCACAAGAGCTGGCG GGGCCAGAT Clone 2 Position in PCR product = 5535-5773 TGTAAGAATGCCTGACAAATAGTGATAACAATAATAACAATTATTATTGTTAAAACTCAG (SEQ ID NO: 14) TATTTATATGGTGCTTACTATGTAACAGGCACTGTTTTAAGTGGTTTATATAAACCATTT GAATTGTAGTAATTAGTCTGTAGTACAGTGATTATCAAATCATAGTAGGAGCTCAGCAAG AATTAGTATTCTTCTAGGTTTTAACCCTTTAAGTTTGTTGCCAAGGAGAATCTCCTCTT Clone 3 Position in PCR product = 5601-6103 GGCCATGTGTGAGGGCTCATGCCTATATAGTCCCAGCGCTTTGGGAGGCTGAGGTGGGAG (SEQ ID NO: 15) GATTGCTTGAGACCAGGAGCTCAAGACTAGTGTGGGCAACATAGTGAAACCCCATCTTTA CAAGAGATAAAGAAAACTAGCCAAGTGTGGTGGTATGTGCCTGTAGTCTCTGCTACTTCA GAGGCTGAGGCAGGAGGATCACTTGAGCCCAAGAGTTCAAGGCTGCAGTGAGCTATGATT GTGCCACTGCACTCCAGCCTGGCTGATAGAGACCCTGTCTTTAAAAAAAAAGAATGGATG TGAGGAATGATGGGAATAGTGTTAAGAGAGTGTAAGAATGCCTGACAAATAGTGATAACA ATAATAACAATTATTATTGTTAAAACTCAGTATTTATATGGTGCTTACTATGTAACAGGC ACTGTTTTAAGTGGTTTATATAAACCATTTGAATTGTAGTAATTAGTCTGTAGTACAGTG ATTATCAAATCATAGTAGGAGCT Clone 4 Position in PCR product = 636-1041 CCATGTGCCTGGCTTCGCCCCACCTGGTTTCAGCTGCTCTTCCTTACCTGCCTCGCCTTT (SEQ ID NO: 16) TACCCTTCCCTGTCTCCTTTCCTCTCCTCAGAGATTCTGCCATTGATGAAGCTGCTGTCC ACTCACCCCTAGATTTTTGTTGCATAGCAGTAAGATCTCTGGCCTGGAATGTTTTGGGGA AAACTGGAAGGACTGTGTTATGGGAGTGGGAGTATAACTGGTACCTGGTTAATGCTTTCC CTTTCCATTATTCTTTTCTTCCTCCAGCCTGGGCAGAGAAACGTGGTTACAAGACAGCCA AGGCGGCTCGGAATGATGTGTACAGAGCAGCCAACAGTCTCTTGCGGCTGGCAGTGGACG GCCGCCTCAGCCTGTGTTTTCATCCCCCAGGCTACAGTGAACAGA Clone 5 Position in PCR product = 2-298 GAGGAACTCAGCACTCATCCTCACCCAGCAGGGCATAAGGGTTTCGGCCAGCCAGGCTGG (SEQ ID NO: 17) ACCCTGGAGCCGAGGTTGGGGTCTCCTCATCCCCTTCTCCCTCCTCATCCGCATCCCGGT CCTCCTCTCCCTCCTCCCCACAGGAGCTGCTCAGCTCTTCCTCTTCCTCCTCCTCCTCGT CACCTGCTGGCCCCACCCTGCCCTGCAAAACCACCAGCTCCGTGGTCTCTGGATGGGACT CCCAGGTGCCTGGGGAACCAAAACAAGAAAAAAATGGAGGAGAGTTTTGAGCAAGAA Clone 6 Position in PCR product = 1-411 CGAGGAACTCAGCACTCATCCTCACCCAGCAGGGCATAAGGGTTTCGGCCAGCCAGGCTG (SEQ ID NO: 18) GACCCTGGAGCCGAGGTTGGGGTCTCCTCATCCCCTTCTCCCTCCTCATCCGCATCCCGG TCCTCCTCTCCCTCCTCCTCACAGGAGCTGCTCAGCTCTTCCTCTTCCTCCTCCTCCTCG TCACCTGCTGGCCCCACCCTGCCCTGCAAAACCACCAGCTCCGTGGTCTCTGGATGGGAC TCCCAGGTGCCTGGGGAACCAAAACAAGAAAAAAATGGAGGAGAGTTTTGAGCAAGAACT AAAGCCAAGGAAAGATGGGGAAGAGGCAAAGACTAGGAATAACAATAATCTTTAGAGCTG CTGGCATTCATTCATTCATCCATTCATTCAACTTCCTATGTGCAGATTGCT Clone 7 Position in PCR product = 3059-3448 CTGAGTAGCTGAGACCACAGGCGTGCGGCTCCACACCTGGCTAACTTTTTGTATTTTTAG (SEQ ID NO: 19) TAGAGATAGGGTTTTGCCATGTTGGCCAGGCTGGTCTCAAACTCCTGACCTCAAGTAATG CGCCTGCCTCAGCCTCCCAAAGTGCTAGGATTACAGGGATGAGCCACCATACCGGCCGCC ACTCATCCTTCTTGATCATAATCCTCTCCCTCTATACATGCAAGCTTTATCCTTTTAAGG AAATCAACTCCTTACATTTCTCTTTAGTTTATGACCTGTGTATCTCTCAACAATGCAGCT TAATTTTGCAGCTTTCAAACTTGATAGAACTGAAATTGTGCAGTATGGATGCTATTGGGT CAGACTCTTTTCACACAATGTTATGTGAAG Clone 8 Position in PCR product = 3492-3772 TAAAAAAAAAGCCATGGAATTGGATGAGATGTAGGAGAGAAAGGAAATAGTTGGAGAAGA (SEQ ID NO: 20) GGAGGTCAAGGACTGAGCCTTAGGACAAGCCAGCATTTAGTTGGGCAAAGGACAGTGAGA AGGAGGAAAACCAAGGGAGCGTCCCAGAAGTCAAATGAAGAAGGTGTTTGAAGAGGAAAG GAGGAATCAGCTGTGTCAACTGTTGCTGACAGGCCAAATGAGAGAACAGAGAGCTGCTCA GCAGGCTTGGCAATGTGAAGATCCGTGGTTTCAGTGGGGTGG Clone 9 Position in PCR product = 1-503 CGAGGAACTCAGCACTCATCCTCACCCAGCAGGGCATAAGGGTTTCGGCCAGCCAGGCTG (SEQ ID NO: 21) GACCCTGGAGCCGAGGTTGGGGTCTCCTCATCCCCTTCTCCCTCCTCATCCGCATCCCGG TCCTCCTCTCCCTCCTCCTCACAGGAGCTGCTCAGCTCTTCCTCTTCCTCCTCCTCCTCG TCACCTGCTGGCCCCACCCTGCCCTGCAAAACCACCAGCTCCGTGGTCTCTGGATGGGAC TCCCAGGTGCCTGGGGAACCAAAACAAGAAAAAAATGGAGGAGAGTTTTGAGCAAGAACT AAAGCCAAGGAAAGATGGGGAAGAGGCAAAGACTAGGAATAACAATAATCTTTAGAGCTG CTGGCATTCATTCATTCATCCATTCATTCAACTTCCTATGTGCAGATTGCTGAACAGAAC CTTTGTGCGCATCAACTTCAATCTTTACAATCACTATGCTAAGGGTCAATTATTACCCTC AGTTTGCAGATCAGGAAAATATC Clone 10 Position in PCR product = 5567-5860 CACTGCACTCCAGCCTGGCTGATAGAGACCCTGTCTTTAAAAAAAAAGAATGGATGTGAG (SEQ ID NO: 22) GAATGATGGGAATAGTGTTAAGAGAGTGTAAGAATGCCTGACAAATAGTGATAACAATAA TAACAATTATTATTGTTAAAACTCAGTATTTATATGGTGCTTACTATGTAACAGGCACTG TTTTAAGTGGTTTATATAAACCATTTGAATTGTAGTAATTAGTCTGTAGTACAGTGATTA TCAAATCATAGTAGGAGCTCAGCAAGAATTAGTATTCTTCTAGGTTTTAACCC Clone 11 Position in PCR product = 9224-9455 CCTACCCGGAAGTCAGAGCTTTGGGGGAAAGCGGGCTGCTACTGGTGAAGACGGTGGGCC (SEQ ID NO: 23) TGGGATGCCACAGTTCTCCGCTAGCCACTCGGCTCCCCACAGCGGGCCGCAGTCTTCCTT TCCAGAGGGGCTGGAGAGAGTTGGGCTTTTAGAAGGAGAAGGCTGAGTATTGCCTGAAAG AAGGACTTGGGGGAAGTCTGACTTGAGAGAGGAGACTTGAACGACTCTGGAG Clone 12 Position in PCR product = 5836-6150 TATCAGCCAGGCTGGAGTGCAGTGGCACAATCATAGCTCACTGCAGCCTTGAACTCTTGG (SEQ ID NO: 24) GCTCAAGTGATCCTCCTGCCTCAGCCTCTGAAGTAGCAGAGACTACAGGCACATACCACC ACACTTGGCTAGTTTTCTTTATCTTTTGTAAAGATGGGGTTTCACTATGTTGCCCACACT AGTCTTGAGCTCCTGGTCTCAAGCAATCCTCCCACCTCAGCCTCCCAAAGCGCTGGGACT ATATAGGCATGAGCCCTCACACATGGCCGTCATCCATTCTTTTACTCAGGTATCAATGTC CTTATTTTTAAAATC Clone 13 Position in PCR. product = 5783-6198 GTGAGGTCTTGAGTAAGTGATTTTGCTACTCTGAGTCTTAGTTACTTTGATTTTAAAAAT (SEQ ID NO: 25) AAGGACATTGATACCTGAGTAAAAGAATGGATGACGGCCATGTGTGAGGGCTCATGCCTA TATAGTCCCAGCGCTTTGGGAGGCTGAGGTGGGAGGATTGCTTGAGACCAGGAGCTCAAG ACTAGTGTGGGCAACATAGTGAAACCCCATCTTTACAAAAGATAAAGAAAACTAGCCAAG TGTGGTGGTATGTGCCTGTAGTCTCTGCTACTTCAGAGGCTGAGGCAGGAGGATCACTTG AGCCCAAGAGTTCAAGGCTGCAGTG Clone 14 Position in PCR product = 5836-6150 TATCAGCCAGGCTGGAGTGCAGTGGCACAATCATAGCTCACTGCAGCCTTGAACTCTTGG (SEQ ID NO: 26) GCTCAAGTGATCCTCCTGCCTCAGCCTCTGAAGTAGCAGAGACTACAGGCACATACCACC ACACTTGGCTAGTTTTCTTTATCTTTTGTAAAGATGGGGTTTCACTATGTTGCCCACACT AGTCTTGAGCTCCTGGTCTCAAGCAATCCTCCCACCTCAGCCTCCCAAAGCGCTGGGACT ATATAGGCATGAGCCCTCACACATGGCCGTCATCCATTCTTTTACTCAGGTATCAATGTC CTTATTTTTAAAATC Clone 15 Position in PCR product = 1-283 CGAGGAACTCAGCACTCATCCTCACCCAGCAGGGCATAAGGGTTTCGGCCAGCCAGGCTG (SEQ ID NO: 27) GACCCTGGAGCCGAGGTTGGGGTCTCCTCATCCCCTTCTCCCTCCTCATCCGCATCCCGG TCCTCCTCTCCCTCCTCCTCACAGGAGCTGCTCAGCTCTTCCTCTTCCTCCTCCTCCTCG TCACCTGCTGGCCCCACCCTGCCCTGCAAAACCACCAGCTCCGTGGTCTCTGGATGGGAC TCCCAGGTGCCTGGGGAACCAAAACAAGAAAAAAATGGAGGAGAGTTTTGAGCAAGAACT AAAGCCAAGGAAAGATGGGGAAGAGGCAAAGACTAGGAATAACAATAATCTTTAGAGCTG CTGGCATTCATTCATTCATCCATT Clone 16 Position in PCR product = 1-307 CGAGGAACTCAGCACTCATCCTCACCCAGCAGGGCATAAGGGTTTCGGCCAGCCAGGCTG (SEQ ID NO: 28) GACCCTGGAGCCGAGGTTGGGGTCTCCTCATCCCCTTCTCCCTCCTCATCCGCATCCCGG TCCTCCTCTCCCTCCTCCTCACAGGAGCTGCTCAGCTCTTCCTCTTCCTCCTCCTCCTCG TCACCTGCTGGCCCCACCCTGCCCTGCAAAACCACCAGCTCCGTGGTCTCTGGATGGGAC TCCCAGGTGCCTGGGGAACCAAAACAAGAAAAAAATGGAGGAGAGTTTTGAGCAAGAACT AAAGCC Clone 17 Position in PCR product = 1230-1484 CAGTACTTTCCTCAATGTCCCACCTTCTCTCTTTCCCTTACCCACCCTCCCCGTCATACC (SEQ ID NO: 29) TGCAACTGCCTAGGCAGAAGAGATGGGAAGATGAGGCCTGGGCAGTCACAGAGCTTCACA GAGGGGGTAAGAAAGTAGGTCTGAAAGTATCGGGTATGGCCCGGGGTTCTGGAGACACTC ACGACTTTCCGCCCCACCAGCCCATTGATCAGCGAGGACTTTCCCACATTAGGGAAACCT GAGGAAGGCAAGGAA Primer set 2 PCR product 5′ and 3′ modified library: Clone 1 Position in PCR product = 2077-2246 AACCCCATCTCTACTAAAAATACAAAAATTAGCTGGGCGTGGTGGTGGGCGCCTGTAATT (SEQ ID NO:30) GCAGCTACTTGGGAGGCTGAGGCAGGAGAACCACTTGAACCCAGGAGGCGGAGGTTGCAG TGAGCTGAGATTGCACCATTGCACTCCAGCCTGGGCAATAAGAGGGAAAC Clone 2 Position in PCR product = 8519-8740 CGGACATCAGCACTAGGTAGAGATTAGAAAGACAGGAAGATAGATACCTCTCTGTCTCCC (SEQ ID NO: 31) AACTCTTGCCTCTGACCTTTGCCCCTGAAAAACCTTTCTCCCTCCTCCTTGCCCACCCTT ATCCCTAGTACTCACTGGATGTCGGATATCAGTGATAAGCAGGACGATGTCAGACATCTC TAACACCCGCCACAGCTGCCTCCATGTCTAAAAAGACAGGAT Clone 3 Position in PCR product = 10096-10485 TTGACGCGGTCCCACGACCCCCTCCCACGATCCCCAGAGGTGCAGCGGGCACACCCCTCC (SEQ ID NO: 32) TTCCAGATGTGCGGAAGCCCGAGCCCCGCCCCCTCCTCCCGCTCCCGCACTGACCTCTCT TCCGCTCCCGTTTGTCCTGCAACTGCTTCTTCTTCTGCTTCACGCTGAATGGCTTCTTCC TCGGCATGGCCCGGACCAGTCACCTGGCCCGCCCTCCGCCGAGCTCCCGCCGCCTCAACT GACTGCCCCCCGGGGCAGCCCCCGCCGCAGGGGCCCGGGACCCTAGAGGAGGCGGGGCTA GCAGGTGACGTCAGCGGGCGGGCCCGACAGAATTACCGCCGCGGCGGCGATGGAAGGCGG ACGGGGGAGATATAGTCACTTCCCTCCAGG Clone 4 Position in PCR product = 1296-1531 GCCCACAGCAGTGTAGGGCTCCTGGATCTGGGCGATAGGGTAGATCCCCGCCAGAACCTG (SEQ ID NO: 33) AGGGAAATGAGCACTCAGTACTTTCCTCAATGTCCCACCTTCTCTCTTTCCCTTACCCAC CCTCCCCGTCATACCTGCAACTGCCTAGGCAGAAGAGATGGGAAGATGAGGCCTGGGCAG TCACAGAGCTTCACAGAGGGGGTAAGAAAGTAGGTCTGAAAGTATCGGGTATGGCC Clone 5 Position in PCR product = 6677-6969 GCTGCCTTTAGCCTTCCCAGTACTTTTCAGAAGCTCAGAGAAACGTGCGTGATTCCAGGG (SEQ ID NO: 34) AGGGTAGGGTCAAATGACTTTTGGGAGATTCTCTGACCTGCTCTTATTTAGGTTGGCACT GTACAACTCCAGAGGGTGCCAGTTACATAATCTGTGCAGGGCACAGTATGTGCCATCATG CACAGCAGCCCTGGGGAGAACCTCTTTAATCTTCTCCTTCTTTGAGCAGTGGACTTGAGC AGCTGGCGGGAGAAGATTGCTCGGGATGTGGCTGGGGCCACCTGGGGTAATGG Clone 6 Position in PCR product = 6349-6508 GAGGTGGAATTTAACTCAGGCTGTCATGATCCTTCCACTGCAGCAGACGCCTCTTCTGCC (SEQ ID NO: 35) TTGCCCACCGCCACTGGCAGAGATCACCCCTCAGACACCCTGGGGCCTAATGAGACCTGA TCGCCCTCTCTCTTCTCCGAATATGAAAACTCTGTACCTC Clone 7 Position in PCR product = 6623-6815 TGCTGCTCCACCAGGACTGCTGGGCCATCCTCCTCCTCCTCCTCCTCCCCAGAGCCATTA (SEQ ID NO: 36) CCCCAGGTGGCCCCAGCCACATCCCGAGCAATCTTCTCCCGCCAGCTGCTCAAGTCCACT GCTCAAAGAAGGAGAAGATTAAAGAGGTTCTCCCCAGGGCTGCTGTGCATGATGGCACAT ACTGTGCCCTGCA Clone 8 Position in PCR product = 4787-4973 ATGGCTGTCACAGCCTCAGGGCTCTACATGATGTGGGCCCTGGTGATCTTGCTGACCTCA (SEQ ID NO: 37) TCCCCAGTACTTTATCCTGGCTCCCATACTCCAATCCCCTGGGCACTCTTGCTGGTCCTA GAATCTCCAAGCCCATTCCCTCCTCAAGACCCTTTCCCCACAGTTCTGAATGGCTCACTT CATCTCA Clone 9 Position in PCR product = 2868-3055 CTTTGACGACCACCACCAGACCTAGTTCTCTGTCCGCTTTGCAGGAAAACTCCTTAAAAG (SEQ ID NO: 38) ACTTACCTACTTTTTTCACCATTTCTTCCTGCTATCTTCTTTGTAACTGTAAACTACAAC ATACAAAAAAATGCACAGAACATACATGTGCAGCCTGATGAACCCCATACCACCCAATGT GTGACAAC

All of the sequences align to the PCR products used to generate the libraries. In the case of the 5′ and 3′ modified library made from ‘primer set 1’ four out of 17 of the sequenced clones have inserts that align to the ends of the original PCR product indicating an overabundance of end-sequences in the 5′ and 3′ modified library prepared from a PCR product generated with 5′ OH unmodified primers. In contrast, zero out of nine of the sequenced clones derived from the 5′ and 3′ modified library made using ‘primer set 2’ have inserts that align to the ends of the original PCR product, indicating that the use of 5′-modified primers to generate the PCR product essentially eliminates the over-abundance of the end-sequences from the 5′ and 3′ modified library. 

The invention claimed is:
 1. A method of reducing representation of the ends of a primary polynucleotide sequence in a library of fragments generated from said primary polynucleotide sequence, the method comprising: a) performing an amplification reaction with a modified forward primer and a modified reverse primer to introduce a modification at or near each 5′ terminus of a double-stranded primary polynucleotide sequence, said modification configured to prevent fragments originating from the ends of the primary polynucleotide from ligating to an adapter, thereby forming a modified primary polynucleotide sequence; b) fragmenting the modified primary polynucleotide sequence such that the 5′ terminal fragment and the 3′ terminal fragment each comprise the modification; c) ligating an adapter to fragments generated in step b), thereby forming a library of fragments generated from said primary polynucleotide sequence.
 2. The method of claim 1, wherein said modified amplification primers comprise a 5′-amino or 5′-biotin modification.
 3. The method of claim 1, wherein said modified amplification primers comprise a modification that prevents nucleotide polymerase mediated copying of the full length of the primer.
 4. The method of claim 3, wherein said modified amplification primers comprise an abasic site.
 5. The method according to claim 1, wherein the fragments of the primary polynucleotide sequences are generated by sonication or nebulization.
 6. The method of claim 1, wherein the modified primary polynucleotide molecules are generated by polymerase chain reaction.
 7. The method of claim 6, wherein the modified primary polynucleotide molecules are at least 5000 base pairs in length.
 8. The method of claim 1, wherein the primary polynucleotide sequence is a genomic DNA fragment.
 9. The method of claim 1, further comprising amplifying fragments ligated in step c).
 10. A method of reducing representation of the ends of a primary polynucleotide sequence in a library of fragments generated from said primary polynucleotide sequence, the method comprising: a) introducing a modification at or near each 5′ terminus of a double-stranded primary polynucleotide sequence, wherein said modification is a modified deoxynucleoside triphosphate introduced using a nucleotide polymerase, said modification configured to prevent fragments originating from the ends of the primary polynucleotide from ligating to an adapter, thereby forming a modified primary polynucleotide sequence; b) fragmenting the modified primary polynucleotide sequence such that the 5′ terminal fragment and the 3′ terminal fragment each comprise the modification; c) ligating an adapter to fragments generated in step b), thereby forming a library of fragments generated from said primary polynucleotide sequence.
 11. The method according to claim 10, wherein said modification is a dideoxynucleoside triphosphate introduced using a terminal transferase.
 12. The method according to claim 10, wherein the fragments of the primary polynucleotide sequences are generated by sonication or nebulization.
 13. The method of claim 10, wherein the primary polynucleotide sequences are DNA molecules.
 14. The method of claim 13, wherein the primary polynucleotide sequence is a genomic DNA fragment.
 15. The method of claim 13, wherein the modified primary polynucleotide molecules are generated by polymerase chain reaction.
 16. The method of claim 10, wherein the modified primary polynucleotide molecules are at least 5000 base pairs in length.
 17. The method of claim 10, further comprising amplifying fragments ligated in step c). 